Method for group interactivity

ABSTRACT

A computer implemented method of generating a scoreboard display comprising capturing and storing digital images at an entertainment venue during an entertainment event, selecting at least one of the captured images including selecting at least one template within which to dispose the selected image, and displaying on the scoreboard the template and the at least one selected digital image disposed therein. The captured image preferably includes a person attending the entertainment event and can be a motion image or a live motion image.

CROSS REFERENCE TO RELATED APPLICATIONS

Reference is made to commonly assigned, co-pending U.S. patent applications:

Ser. No. 12/512,067 by Ptucha et al., filed Jul. 30, 2009 entitled “System for Matching Artistic Attributes of Secondary Image and Template to a Primary Image”;

Ser. No. ______ by Ptucha et al. (Docket 95752) filed of even date herewith entitled “Camera and display system interactivity”;

Ser. No. ______ by Ptucha et al. (Docket 95753) filed of even date herewith entitled “Display system for personalized consumer goods”;

Ser. No. ______ by Ptucha et al. (Docket 95754) filed of even date herewith entitled “Group Display System”; and

Ser. No. ______ by Ptucha et al. (Docket 95446) filed of even date herewith entitled “Method for Interactive display” the disclosures of which are incorporated herein by reference in their entireties.

FIELD OF THE INVENTION

The present invention relates to computer systems, methods, and software programs for use in making digital image products and digital image displays. In particular, the present methods and apparatuses automatically search for, find, evaluate, and arrange digital images in a digital image template according to programmed artistic designs.

BACKGROUND OF THE INVENTION

Personalized image collages, clothing, albums and other image enhanced items are becoming increasingly more accessible as digital printing technologies improve. However, as personalized image bearing products have become more accessible, consumers have become more discriminating. In particular, consumers now seek methods and systems that produce customized image products in a more convenient, faster, seamless, automatic, and integrated manner. While becoming somewhat more common, many items for displaying and/or including embedded customized images are still considered novelties. Methods for recognizing image contents that fulfill a predescribed aesthetic appearance often fall short of expectations. For example, many products with customizable embedded images include photos of people. For this type of product, it would be desirable to identify images that satisfy preselected artistic criteria and/or image attributes, such as number of persons pictured, who is pictured, what zoom ratio, temporal aspects, clothing, background, season, facial expressions, hue, colorfulness, texture, and sharpness, etc. Because some artistic aesthetic elements work better for certain product formats, it would also be desirable if multiple image attributes including aesthetic criteria could be evaluated in parallel for a number of images, and the images with the highest fitness score be automatically determined by computer algorithm. Furthermore, customer satisfaction can be improved if the customer can select a favorite image, or several favorite images, to be included in an image enhanced product. Attributes from this favorite image can be extracted in real time from the image itself, read from a file associated with the image, such as a metadata file, a DPOF file, or a file stored by a user, or it can be generated in some other fashion, or even input directly by a user, and then be used in coordinating surrounding image and template contents. Conversely, attributes of a selected image product template can be used in coordinating which image or images from a user collection can be placed within the template. Furthermore, attributes of a context or of an environment where the image will be displayed can be input to a computer system and referenced to select appropriate templates and images, or any combination of these algorithms can be integrated in a computing system or method.

The problem in the prior art is the time consuming process requiring users to manually search through many images and compose their own artistic creations, for which they may not be capable.

SUMMARY OF THE INVENTION

A preferred embodiment of the present invention includes a computer implemented method of generating an image display, comprising the steps of automatically selecting from a template database a digital image template having template attributes and having at least one designated location for disposing a digital image. The digital images are obtained by capturing digital images in an electronic camera and transmitting the captured images to the designated location. Each of the captured digital images comprises a plurality of image elements. At least one of the digital images are automatically selected based on its image elements corresponding to the template attributes, and disposing the at least one selected digital image in a designated template location and displaying on an electronic display the digital template with the at least one selected image disposed in the designated location. The digital image can be a still image, a stored motion digital image, or a live motion digital image. The step of receiving includes the step of receiving the digital images over a wireless network or over a hardwired LAN. The method further comprises situating the camera or cameras and the display at a stadium, arena, or other event and displaying the template to a plurality of people and the selected image includes at least one of the plurality of people. The camera can be hand carried or a mounted stationary camera at the event or stadium.

Another preferred embodiment of the present invention is a computer implemented method of generating a scoreboard display comprising capturing and storing digital images at an entertainment venue during an entertainment event, selecting at least one of the captured images including selecting at least one template within which to dispose the selected image, and displaying on the scoreboard the template and the at least one selected digital image disposed therein. The captured image preferably includes a person attending the entertainment event and can be a motion image or a live motion image.

These, and other, aspects and objects of the present invention will be better appreciated and understood when considered in conjunction with the following description and the accompanying drawings. It should be understood, however, that the following description, while indicating preferred embodiments of the present invention and numerous specific details thereof, is given by way of illustration and not of limitation. Many changes and modifications may be made within the scope of the present invention without departing from the spirit thereof, and the invention includes all such modifications.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-B illustrate a server/workstation, large display, and image capture device computer systems for use in preferred embodiments of the present invention.

FIG. 2 illustrates a user implementing a computer system in a preferred embodiment of the present invention.

FIG. 3 illustrates a digital template design in a preferred embodiment of the present invention.

FIG. 4 illustrates programming of required image attributes with weighted values.

FIG. 5 illustrates a method and results of a compatibility score calculation.

FIG. 6 illustrates image selection based on compatibility evaluation and image adjustment.

FIG. 7 illustrates a flowchart for template selection.

FIG. 8 illustrates a flowchart for image selection.

FIG. 9 illustrates a flowchart for image selection.

FIG. 10 illustrates a flowchart for template selection.

FIG. 11 illustrates a flowchart for image selection.

FIGS. 12A-13 illustrates algorithms for image searching and compatibility scoring.

FIG. 13 illustrates examples of recorded metadata.

FIG. 14 illustrates examples of extracted metadata.

FIG. 15 illustrates a camera and display system of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 illustrates a first embodiment of an electronic system 26, a computer system, for implementing certain embodiments of the present invention for automatically generating image enhanced products. In the embodiment of FIG. 1, electronic computer system 26 comprises a housing 22 and a source of content and program data files 24 such as software applications, template designs and recipes, image files, image attributes and required image attributes, which includes various memory and storage devices 40, a wired user input system 68 as well as a wireless input system 58, and an output system 28, all communicating directly or indirectly with processor 34. Although not shown processor 34 is meant to illustrate typical processor system and chip components such as instruction and execution registers, an ALU, various levels of cache memory, etc. The source of program and content data files 24, user input system 68, or output system 28, and processor 34 can be located within housing 22 as illustrated. In other embodiments, circuits and systems of the source of content and program data files 24, user input system 68 or output system 28 can be located in whole or in part outside of housing 22. As an example, element 68 b illustrates a screen pointer control embodied as a mouse when located outside the housing 22 but can be an embedded trackball when located within housing 22.

The source of content or program data files 24 can include any form of electronic, optical, or magnetic storage such as optical discs, storage discs, diskettes, flash drives, etc., or other circuit or system that can supply digital data to processor 34 from which processor 34 can load software, template designs and recipes, derived and recorded metadata, image files, image attributes and required image attributes or derive images and image metadata for use in automatically forming an image enhanced item. In this regard, the content and program data files can comprise, for example and without limitation, software applications, a still image data base, image sequences, a video data base, graphics, and computer generated images, image attribute information associated with still, video, or graphic images, and any other data necessary for practicing embodiments of the present invention as described herein. Source of content data files 24 can optionally include devices to capture images to create content data for use in content data files by use of capture devices located at electronic computer system 20 and/or can obtain content data files that have been prepared by or using other devices or image enhancement and editing software. In the embodiment of FIG. 1, sources of content or program data files 24 includes sensors 38, a memory and storage system 40 and a communication system 54.

Sensors 38 are optional for particular embodiments of the present invention and can include light sensors, biometric sensors and other sensors known in the art that can be used to detect conditions in the environment of system 26 and to convert this information into a form that can be used by processor 34 of system 26. Sensors 38 can also include one or more cameras, video sensors, scanners, microphones, PDAs, palm tops, laptops that are adapted to capture images and can be coupled to processor 34 directly by cable or by removing portable memory 39 from these devices and/or computer systems and coupling the portable memory to slot 46. Sensors 38 can also include biometric or other sensors for measuring involuntary physical and mental reactions. Such sensors including, but not limited to, voice inflection, body movement, eye movement, pupil dilation, body temperature, and p4000 wave sensors.

Memory and storage 40 can include conventional digital memory devices including solid state, magnetic, optical or other data storage devices, as mentioned above. Memory 40 can be fixed within system 26 or it can be removable and portable. In the embodiment of FIG. 1, system 26 is shown having a hard disk drive 42, which can be an attachable external hard drive, which can include an operating system for electronic computer system 26, and other software programs and applications such as the program algorithm embodiments of the present invention, a template design data base and a recipe data base, derived and recorded metadata, image files, image attributes and required image attributes, software applications, and a digital image data base. A disk drive 44 for a removable disk such as an optical, magnetic or other disk memory (not shown) can also include control programs and software programs useful for certain embodiments of the present invention, and a memory card slot 46 that holds a removable portable memory 48 such as a removable memory card or flash memory drive or other connectable memory and has a removable memory interface 50 for communicating with removable memory 48, if necessary. Data including, but not limited to, control programs, template designs and recipes, derived and recorded metadata, image files, image attributes and required image attributes, software applications, digital images and metadata can also be stored in a remote memory system 52 such as a personal computer, computer network, a network connected server, or other digital system.

In the embodiment shown in FIG. 1, system 26 has a communication system 54 that in this embodiment can be used to communicate with an optional remote input 58, remote memory system 52, an optional a remote display 56, for example by transmitting image designs in the form of template designs with or without merged images and receiving from remote memory system 52, a variety of control programs, template designs and recipes, derived and recorded metadata, image files data bases, image attributes, required image attributes, and software applications. Although communication system 54 is shown as a wireless communication system, it can also include a modem for coupling to a network over a communication cable for providing to the computer system 26 access to the network and remote memory system 52. A remote input station including a remote display 56 and/or remote input controls 58 (also referred to herein as “remote input 58”) can communicate with communication system 54 wirelessly as illustrated or, again, can communicate in a wired fashion. In a preferred embodiment, a local input station including either or both of a local display 66 and local user input controls 68 (also referred to herein as “local user input 68”) is connected to processor 34 which is connected to communication system 54 using a wired or wireless connection.

Communication system 54 can comprise for example, one or more optical, radio frequency or other transducer circuits or other systems that convert data into a form that can be conveyed to a remote device such as remote memory system 52 or remote display 56 using an optical signal, radio frequency signal or other form of signal. Communication system 54 can also be used to receive a digital image and other data, as exemplified above, from a host or server computer or network (not shown), a remote memory system 52 or a remote input 58. Communication system 54 provides processor 34 with information and instructions from signals received thereby. Typically, communication system 54 will be adapted to communicate with the remote memory system 52 by way of a communication network such as a conventional telecommunication or data transfer network such as the internet, a cellular, peer-to-peer or other form of mobile telecommunication network, a local communication network such as wired or wireless local area network or any other conventional wired or wireless data transfer system.

User input system 68 provides a way for a user of system 26 to provide instructions to processor 34, such instructions comprising automated software algorithms of particular embodiments of the present invention that automatically generate artistic coordinated image displays according to template recipes. This software also allows a user to make a designation of content data files, such as selecting image templates and designating primary images, to be used in automatically generating an image enhanced output product according to an embodiment of the present invention and to select an output form for the output product. User controls 68 a, 68 b or 58 a, 58 b in user input system 68, 58, respectively, can also be used for a variety of other purposes including, but not limited to, allowing a user to arrange, organize and edit content data files, such as coordinated image displays and image templates, to be incorporated into the image enhanced output product, for example, by incorporating image editing software in computer system 26 which can be used to override automated image enhanced output products generated by computer system 26, as described below in certain embodiments of the present invention, to provide information about the user or audience, to provide annotation data such as voice and text data, to identify characters in the content data files, and to perform such other interactions with system 26 as will be described later.

In this regard user input system 68 can comprise any form of device capable of receiving an input from a user and converting this input into a form that can be used by processor 34. For example, user input system 68 can comprise a touch screen input 66, a touch pad input, a 4-way switch, a 6-way switch, an 8-way switch, a stylus system, a trackball system, a joystick system, a voice recognition system, a gesture recognition system, a keyboard 68 a, mouse 68 b, a remote control or other such systems. In the embodiment shown in FIG. 1, electronic computer system 26 includes an optional remote input 58 including a remote keyboard 58 a, a remote mouse 58 b, and a remote control 58 c. Remote input 58 can take a variety of forms, including, but not limited to, the remote keyboard 58 a, remote mouse 58 b or remote control handheld device 58 c illustrated in FIG. 1. Similarly, local input 68 can take a variety of forms. In the embodiment of FIG. 1, local display 66 and local user input 68 are shown directly connected to processor 34.

A simplified block diagram of a camera 76 of the present invention is shown in FIG. 1B. In this illustration, a removable portable memory card 157 of the camera can be coupled to computer system server 26 via the computer system memory card reader 46, previously described. The camera 76 includes an optical section 151 for imaging a scene upon an image sensor 152 and generating an image signal, an A/D converter 153 for digitizing the image signal, and a liquid crystal display (LCD screen) 154 for displaying images, templates, recipes, as described below, and other information similar to that displayable upon computer display 66 described earlier. Other display screen technologies may be used, e.g. OLED displays, for example. A number of user input buttons 155, operating in a fashion similar to that of user input control section 68 described previously for the computer system 26, and both internal memory 156 and a removable memory card 157 for storing templates, recipes, captured images, digital video, image databases, image attributes, required image attributes, content files, software applications for image processing, etc., and other program algorithms for execution by processor 158. Similar to computer system processor 34, camera processor 158 may include a plurality of instruction registers, an ALU, and caches for executing programs. Processor 158 may be manufactured as an integrated circuit on a single silicon chip or may be assembled as a chipset comprised of several silicon chips. The camera includes an internal communications interface 161 (e.g. wired or wireless modem). Camera 76 can include a camcorder for recording video or sufficient memory for recording digital video. The processor 158 generally controls the operation of the camera 76, and interchanges data through a memory card interface 159 with the memory card, and through a PC interface 160 with the computer system and/or server 26, through a direct computer system interface 160, or through the communications interface 161 with a wired or wireless communications network (not shown) to computer system and/or server 26. The camera can be hand carried by a cameraman or can be mounted to a stationary object and remotely controlled.

The camera includes software applications for running on computer system 26 that enables the user to download applications through interface 160 into camera memory 156 or 157. The user can also select, through the software application, various program features of the application using buttons 155 to navigate through various menu features shown on display screen 154 which provides interactive feedback through a camera GUI, for example, as is well known in the art. All of this information can alternatively be preloaded on the camera during manufacturing or downloaded, via the web or a memory card reader 46 on the host computer system 26, to the removable memory card 157, which can be subsequently inserted into the camera. Typically, keyword descriptors accompany the information to enable easy access by the camera user.

A cameraman operates camera 76 to store images and/or video, which are stored either in the internal memory 156 or in the memory card 157 (or in both). After recording, the cameraman can review the images on the LCD screen 154, using the buttons 155 to scroll through the images or can upload video and images to server 26. Operators can, or under program control the server 26 can, select the desired template recipes and run the template recipe algorithms as will be described below in more detail. For example, operator options include selection of templates and recipes, selection of images and image manipulation software, and selection of template backgrounds and text.

These applications and options are stored in and accessed from server 26 or camera memory 156, memory card 157. The camera display screen can be used to monitor the look of a coordinated image template design in progress or a completed template design. The camera is connected to a wired or wireless modem, such as through communications interface 161. In this case, images and video are transmitted to computer system 26 which, in turn, processes received images according to recipe programs and transmits selected images to display 190, which can also be simultaneously displayed on operator display 66 for monitoring purposes.

If the camera includes a transmitter, e.g., a network connection in the communications interface 161, the camera could include and initiate a “send” command that the cameraman would enable after recording motion or still images. This command automatically sends image data through the coupled network wirelessly to the central server using the appropriate communications protocol (FTP, mailto, etc.). Instead of, or in addition to, the cameraman transmits several completed image files via the network connected to the server, which is also be monitored by an operator or, alternatively, could be program controlled.

As is illustrated in FIG. 2, computer system 26 and local user input 68 can take the form of an editing studio or kiosk 70 (hereafter also referred to as an “editing area 70”), although this illustration is not intended to limit the possibilities as described in FIG. 1 of editing studio implementations. In this illustration, a user 72 is seated before a console comprising local keyboard 68 a and mouse 68 b and a local display 66 which is capable, for example, of displaying multimedia content. As is also illustrated in FIG. 2, editing area 70 can also have sensors 38 including, but not limited to, camera or video sensors 38, audio sensors 201 and other sensors such as, for example, multispectral sensors that can monitor user 72 during a user or production session.

Output system 28 (FIG. 1) is used for rendering images, text, completed or uncompleted digital image templates, or other graphical representations in a manner that allows an image enhanceable item to be converted into an image enhanced product or display, such as a digital frame, LCD display, photo album, or collage. In this regard, output system 28 can comprise any conventional structure or system that is known for printing, displaying, or recording images, including, but not limited to, printer 29. For example, in other embodiments, output system 28 can include a plurality of printers 29, 30, wherein processor 34 is capable of printing to a plurality of printers or a network of printers. Each printer of the plurality of printers can be of the same or a different type of printer than at least one other of the plurality of printers, and each printer can produce prints of the same or a different format from others of the plurality of printers. Printer 29 can record images on a tangible surface, such as on, for example, various standard media or on clothing such as a T-shirt, using a variety of known technologies including, but not limited to, conventional four color offset separation printing or other contact printing, silk screening, dry electrophotography such as is used in the NexPress 2100 printer sold by Eastman Kodak Company, Rochester, N.Y., USA, thermal printing technology such as in thermal printer 30, drop on demand ink jet technology and continuous inkjet technology. For the purpose of the following discussions, printers 29, 30 will be described as being of a type that generates color images. However, it will be appreciated that this is not necessary and that the claimed methods and apparatuses herein can be practiced with printers 29, 30 that prints monotone images such as black and white, grayscale or sepia toned images.

In certain embodiments, the source of content data files 24, user input system 68 and output system 28 can share components. Processor 34 operates system 26 based upon signals from user input system 58, 68, sensors 38, memory 40 and communication system 54. Processor 34 can include, but is not limited to, a programmable digital computer, a programmable microprocessor, a programmable logic processor, a series of electronic circuits, a series of electronic circuits reduced to the form of an integrated circuit chip, or a series of discrete chip components.

As used herein, an embodiment of an image enhanceable item 300, such as the example frame shown in FIG. 3, can include anything that has a tangible surface 302 with which an image can be formed, displayed, popped in, inserted, attached, adhered, located, embedded, placed or otherwise provided. In addition, an image enhanceable item can be extended to include non-tangible items such as holograms or other digitally controlled virtual displays. An image enhanceable item or items can be saved on various recording media for playback on digital displays, projectors, home theater systems as slideshows. For example and without limitation, an image enhanceable item 300 can be formed in various shapes such as heart shaped, a person's profile, the shape of a geological area, or any other shape. The tools and techniques for generating image templates of various shapes, in general, are well known in the art and are not described further herein as to their initial creation. It can also take the form of a collage, photo book, scrap book, photo calendar, mug, stein, cup, stemware, jewelry, tile, mosaic, home décor, mouse pads, pillowcases, pen & pencil holders, a simulated or actual brushstroke image on canvas, a photo-realistic image on a canvas, a keepsake box, a fleece blanket, coasters, frames, ornaments, round ornament, snowflake ornament, filigree ornament, pewter ornament, holiday ornament set, annual ornament set, playing cards, puzzle, teddy bear or other stuffed animal, wall paper, packaging, apparel & accessories, including, but not limited to, a T-shirt, a tie, a tote bag, apron, baby onesie, performance shirt, and/or frame, matte and image combinations and collages, mailing labels, gift tags stamps, or any other tangible item.

In addition, other embodiments of an image enhanceable item are also contemplated. Embodiments of the present invention also include electronic displays such as picture frames, digital store front displays, digital projectors, score boards such as in a stadium, or elsewhere, billboards, and interactive displays. Such displays have spatial and temporal components which are described below. The temporal component can be used to display transient information, advertising, artistic content, and can be saved for later display.

Thus, the image enhanceable item 300 as shown in FIG. 3 can be an electronic digital display, or template. In this form, the electronic “virtual” display as shown can realistically represent an actual frame available at a retail location that provides a kiosk that includes the software and/or computer system of the present invention. A user activates the kiosk to automatically generate an artistically coordinated image display, such as the “virtual” template with virtual windows or openings shown in FIG. 3 displayed on screen 66 of computer system 26, with the user's images merged therein. The user can select this virtual template image to be printed on attached printer 29. A print of this electronic virtual template display, with the user's digital images located in the electronic virtual windows therein, can then be inserted or located in the actual frame available at the retail location so that the printed images align with actual physical openings, or windows, in the frame. The “virtual” openings 306, 308, and 310 on the display can be used to display images or videos or a combination of both. The color and texture of an electronically displayed template 312 can be selected to resemble any material. In a preferred embodiment, the texture can be selected to resemble an actual tangible picture frame which a user can purchase. This allows the user to experience the actual look and feel of the frame containing his or her images placed in the windows before printing the completed template design. The user can select alternate templates to be displayed with the same images disposed therein or with a new set of images, under control of the software embodiments of the present invention being run on the computer system 26, as described previously. The display template 300 shown in FIG. 3 can be formed in any shape, such as an oval, diamond, trapezoid, or any other regular or irregular shape. The openings 306, 308, and 310 in the electronic display format can also be shaped and patterned, in any form or shape and in any number and location within the template. The template described above and any images or videos disposed therein can be displayed on an electronic display 66 coupled to the computer system 26 as described above. The background 312 of the template can include decorative background images 320, 330, or videos to enhance or complement the look and feel of the images or videos disposed in other ones of the openings. In such a format, the frame would consist of a digital picture frame circuit controlling the display in one or more of windows 306, 308, 310, and having remaining openings therein to display image prints. Thus, one or more of the windows 306, 308, 310 would be an electronic LCD or OLED display, or other display technology, and the remaining windows used for disposing printed images. Any one or more of the openings 306, 308, 310 can include single images or single videos while other openings can display changing images or videos. Such images or videos can include transitions (a still or motion image that changes over to another still or motion image, which can be the same or different from a current still or motion image) that can be separately timed or can occur simultaneously with transitioning images or videos displayed in other openings. An advantage of certain embodiments of the present invention is that various combinations of images, videos, frame designs, etc. can be displayed, under user control, in alternative forms as a virtual template on a display of computer system so that a user can select a desired look for an image enhanced product. If the electronic virtual template as shown in FIG. 3 is used as a template for display on a scoreboard at a stadium event, for example, the openings can be used to display live feeds from any number of selectable cameras situated in different locations at the stadium.

It is the intent of particular embodiments of the present invention to set forth a language, method, program, or mechanism for an artist to describe his/her aesthetic intent for each template window or template opening and for the image display overall, and for this intent to be fulfilled in an automatic manner on images in real time using a computer system such as illustrated in FIGS. 1-2. The description, program, mechanism or language for each template window opening has been referred to as a recipe, formula, or as required image attributes, which are described in more detail below. These formulas can be designed by artists, designers, celebrities, sports stars, or others; transmitted and/or loaded and stored in computer system storage 40 for repeated use by any number of users of computer system 26. The formulas for the openings can be independent of the template used. An overall template recipe comprising a number of window recipes, however, is typically designed for an overall look and feel of a template and its merged images, and can be stored a template recipe file. In a preferred embodiment, the template recipe file is named so that the aesthetic effect of the template recipe is evident to users. For example, file name “Fall Colors” can identify for a user the look and feel that will be automatically generated by selecting and activating such a template recipe on computer system 26.

As another example of the operation of an embodiment of the present invention, with a template containing two window openings, we have left and right required image attributes or left and right recipes or left and right formulas. The recipe for the opening on the left may dictate that we have a colorful non-person main subject image which fills the opening at a 120% zoom. The recipe for the opening on the right may dictate that we have a landscape image with two people; both facial poses are directed slightly to the left, each face having a 20% fill factor and both faces be offset to the left by 20%. In order to fulfill the recipes each of a plurality of computer system accessible images is evaluated, via programmed computation as described below, based on a fitness measure that calculates an image's compatibility with an opening's required image attributes, for each image with respect to satisfying the recipes for the virtual frame openings. Thus, some images might better satisfy a template opening recipe than another image as indicated by a higher score, evaluation, or compatibility calculation. The images with the highest score, automatically obtained by executing the programming, for each window opening, as against a number of stored images, is automatically chosen to fill each window opening without requiring user intervention in most instances. For most cases, the user merely needs to provide a number of digital images to the computer system, e.g. attaching a flash drive at slot 46 that contains some or all of the user's image files and, in certain, but not all, embodiments of the present invention, the user also selects a favorite image or images which is then used by the computer system as a basis to automatically select remaining images to fill out a template display and/or to automatically select a template. The user may also provide a network server location to the computer system where some or all the user's images are located. The network connected computer system will then retrieve these images for use in generating a completed image display template.

Alternatively, the scoring computation can be programmed such that an optimum arrangement of images in the window openings is one that generates an overall highest score for the entire template. An arrangement that generates the highest overall score is chosen. Identifiable or measurable characteristics that might be included to affect score calculations include, but are not limited to, identity of main subject, main subject size, number of faces, face size, facial pose, facial expression, age/gender of face, dominant color, texture analysis, object match, and time stamp. Time stamps can be effective to search for and find images captured during a particular season. These various characteristics of images are referred to herein as metadata or metadata tags, and are described in more detail below. Metadata can be recorded in association with digital images as derived (extracted) metadata, or as static (recorded) metadata. Typically, users can provide recorded metadata directly by operation of a camera or by later opening image files on a computer system and providing recorded metadata for storage at that time. Almost all digital cameras associate and store metadata with image files captured by the camera, such as time stamps, focal settings, file names, GPS location data, etc. Extracted metadata is obtained by processing image data files, either by a camera's computer system or other external hand held, or workstation, kiosk, or laptop computer system, using programmed algorithms for extracting characteristics in the image. A reference which explains computerized facial age estimation of persons in digital images is Lobo and Kwon, “Automatic Feature Detection and Age Classification of Human Faces in Digital Images”, U.S. Pat. No. 5,781,650. A reference that discusses computer executed facial expression determination is described in Yin, Loi, Xiong, “Facial Expression Analysis Based on Enhanced Texture and Topographical Structure”, Conference Proceedings—IEEE International Conference on Systems, Man and Cyberneteics, v1, P 586-591, 2004. A reference that describes digital gender estimation is Tivive, Bouzerdoun, “A Gender Recognition System Using Shunting Inhibitory Convolutional Neural Networks”, IEEE International Conference on Neural Networks—Conference Proceedings, p 5336-5341, 2006. These three references are incorporated herein by reference in their entirety. “Recipes” are discussed below with respect to preferred embodiments of the present invention.

A majority of keepsake photographic memories contain pictures of people, and, as such, people are often the main subjects in images and, therefore, often may be critical in fulfilling recipe requests. Using computer methods described in U.S. Pat. No. 7,508,961B2 by Chen, Nicponski, and Ray, or P. Viola and M. Jones, “Rapid object detection using a boosted cascade of simple features,” in Computer Vision and Pattern Recognition, 2001, Proceedings of the 2001 IEEE Computer Society Conference, 2001, pp. 1-511-1-518 von, or Schnieiderman, H. Schneiderman, “Feature-centric evaluation for efficient cascaded object detection,” in Computer Vision and Pattern Recognition, 2004. Proceedings of the 2004 IEEE Computer Society Conference, 2004, pp. II-29-II-36 Vol. 2, the size and location of each face can be found within each image. These three documents are incorporated by reference herein in their entirety. Viola utilizes a training set of positive face and negative non-face images. Then, simple Haar-like wavelet weak classifier features are computed on all positive and negative training images. While no single Haar-like feature can classify a region as face or non-face, groupings of many features form a strong classifier that can indeed be used to determine if a region is a face or not. This classification can work using a specific size window. This window is slid across and down all pixels in the image looking for faces. Then the window is enlarged and larger faces are scanned in the image. The process repeats until all faces of all sizes are found in the image. Because this process can be quite compute intensive, optimizations such as an integral image and cascades of weak classifiers makes the process work faster. Not only will this process find all faces in the image, it will return the size of each face. Similar techniques can be used to find the location and size of any non-deformable object such as people, cakes, balloons, graduation caps, cars, boats, and other desirable objects.

Once a face is found, neural networks, support vector machines, or similar classifying means can be trained to locate specific features such as eyes, nose, and mouth; and then corners of eyes, eye brows, chin, and edge of cheeks can be found using geometric rules based upon anthropometric constraints such as those described in DeMenthon, Daniel F, Davis, Larry S., “Model Based Pose in 25 Lines of Code”, Proceedings from the Image Understanding Workshop, 1992. Active shape models as described by Cootes, T. F. Cootes, C. J. Taylor, D. H. Cooper, and J. Graham in “Active shape models—their training and application,” Computer Vision and Image Understanding, vol. 61, pp. 38-59, 1995, can be used to localize all facial features such as eyes, nose, lips, face outline, and eyebrows. These two publications are incorporated by reference herein in their entirety. Once all features are found, it is possible to determine if eyes/mouth are open, or if the expression is happy, sad, scared, serious, neutral, or if the person has a nice smile. Determining pose uses similar extracted features. A. Savakis, M. Erhard, J. Schimmel, and J. Hnatow in “A multi-camera system for real-time pose estimation,” Bellingham Wash., 2007, developed a geometric model that adhered to anthropometric constraints. This document is incorporated by reference herein in its entirety. With pose and expression information stored as metadata for each image, the present invention can give the artist more functionality to define increasingly nuanced image enhanced products by allowing the artist to specify in a window recipe, for example, a person looking to the left with a serious demeanor.

In many instances there are no people depicted in an image, but there is a main subject that is not a person or that does not contain a recognizable face. A main subject detection algorithm, such as the one described in U.S. patent application Ser. No. 09/223,860, filed Dec. 31, 1998, which is incorporated herein by reference in its entirety, can be used to search for and find an image to fill each opening in an aesthetic manner according to stored recipes. Such a recipe might require a particular object to be present in an image which is searchable by virtue of that object being identified in the metadata associated with an image. The metadata for images in a data base of images is searched and those images whose metadata satisfies the search are found and evaluated according to programmed evaluation procedures which are typically defined as calculations to provide a compatibility index as between a found image and a template opening's required image attributes.

Other exemplary embodiments of such algorithms involve segmenting the image into a few regions of homogeneous properties such as color and texture. Region segments can be further grouped into larger regions based on similarity measures. Regions are algorithmically evaluated for their saliency using two independent yet complementary types of saliency features—structural saliency features and semantic saliency features. The structural saliency features are determined by measurable characteristics such as location, size, shape and symmetry of each region in an image. The semantic saliency features are based upon previous knowledge of known objects/regions in an image which are likely to be part of foreground (for example, statues, buildings, people) or background (for example, sky, grass), using color, brightness, and texture measurements. For example, identifying key features such as flesh, face, sky, grass, and other green vegetation by algorithmic processing are well characterized in the literature. The data for both semantic and structural types can be integrated via a Bayes net as described by Russell and Norvig, “Artificial Intelligence—A Modem Approach,” 2^(nd) Edition, Prentice Hall, 2003, to yield the final location of the main subject. This document is incorporated by reference herein in its entirety. Such a Bayes net combines the prior semantic probability knowledge of regions, along with current structural saliency features into a statistical probability tree to compute the specific probability of an object/region being classified as main subject or background. The main subject detection algorithm provides the location of a main subject and the size of the subject as well.

Using recipes, an artist may design and store in the computer system memory creative required image attributes for a number of template openings defining an image template recipe, thereby creating several aesthetic or practical looks for a single image enhanced item. A retail store that provides the tools described herein for customer use and purchase can choose to roll out new looks for each season, holiday, or other occasions. A store that provides these product services can license recipes to or from famous artists or celebrities. An aesthetic look can also be achieved by programmed computer system analysis of a user's images or from a user's selection of a primary or favorite image or images, determining a theme or pre-determined look from image to image, and then picking a template that is complementary to that theme or look. A preferred embodiment of the present invention contemplates an initial step of characterizing images in order to select a template based on those characterizations, and also contemplates an initial selection of a template in order to identify appropriate images for inclusion. In each case, recorded image metadata is used, or is generated by extraction and stored with the images, and is compared with metadata stored with an image template to evaluate, via an evaluation procedure, compatibility between them. A preferred embodiment of the present invention extracts characteristics of a user's designated favorite image or images and incorporates those characteristics in window recipes for remaining openings in a template.

Another embodiment of the present invention includes computer system analysis of digital images for information content such as number of people and/or their expressions and/or color content, then the images are computationally evaluated against selected aesthetic intents as defined by a template or window recipe, where such artistic or aesthetic intents include specific design layouts, each layout being created in advance by an artist or someone skilled in the art of making an image layout pleasing or enticing. For a tangible consumer product, such as a collage, frame, or photo book, the intent may include making something pleasing, creative, fun, inspirational, romantic, or to invoke past memories. For transient displays, such as the electronic displays described above, the intent can be the same as for image enhanceable consumer products, such as digital picture frames or cameras, but may be quite different for commercial applications using electronic displays of various sizes. The following are examples of commercial applications: a digital storefront may be continually updating its product line in an attractive and enticing manner, an embodiment of the present invention may include a large or small digital display in a storefront window. An alternative embodiment may include a user interactive display. A news billboard intent may be to group images by subject and relevance. A sports venue billboard or scoreboard may include displaying pictures that work well together gathered from a continual scanning and capturing of images of the attending crowd or other scenes in or near the sports venue. An interactive display can have a mix of live video frames and pre-existing digital libraries and update its content based upon user input, where the user input can be received via a traditional mouse and keyboard, or may be haptic interfaces, or the display may update its content automatically by detecting a user's facial expression and user activity, and selecting those kinds and types of images for display that elicit a particular electronically detected response. The aesthetic intent that scores highest, or works best for that particular image set is chosen automatically for display or inclusion in an image enhanceable product. Scoring is symmetric in that a template can be selected in advance and the highest scoring images are included, or one or more images can be selected in advance, and then the highest scoring template is selected based on its aesthetic compatibility with the selected images. Alternatively, when creating image enhanceable consumer products, the top n highest scoring images/templates/recipes can be presented to the customer on a computer system display, who in turn picks the image/template/recipe of his/her choice and communicates such a choice to the computer system via the user input controls.

Given an aesthetic look defined by a recipe, filling each window in an image enhanceable item can be done in at least two ways. If there are n windows and n images, a preferred embodiment of the method of the present invention can include computing all possible combinations of all images contained in an image data base in each window. If there are n windows in a virtual image template and m images in an image database, where m>n, a preferred embodiment of the present invention could have many variations to score. In the latter condition, a preferred embodiment of the invention is to place the image with the highest score into each window. In this example, each image is scored by programmed computation against each window recipe individually, and the image with the highest compatibility score for a particular window gets assigned or selected to that particular window. If an image is calculated to have a highest score that is identical in greater than one window, the window with the higher weight is considered more important and will be used to display the high scoring image. Template window weighting is described in more detail below where priority of template windows correspond to the numbering of the windows in a template. If multiple images are scored equivalently for a single window opening, metadata fields that record the number of times an image was accessed can be used to break a tie. To resolve ties, an algorithm that randomly selects an image from the group can be used. The use of weighted values for images and for template openings is described in more detail below.

Another common template recipe generation and fulfillment technique is image splitting. Image splitting is the process of taking a single customer image, and spanning that one image over 2 or more window openings. For example, the program can receive as input a single picture of a bride and groom. An application of a particular recipe will result in the bride being placed in the left window with the groom in the right window. An artist will be able to define and store recipe requirements for the size, location, and spacing of two people in a single photograph. The customer images in a product order can be analyzed using the aforementioned methods. An image with a highest score can be chosen to fulfill the product intent. If no images score above a defined threshold, the algorithm can be designed so that a different recipe is automatically chosen and the process repeats itself with the new recipe.

Often, when doing image splitting, it is necessary to know not only where the main subject is, but also to know the detail surrounding the main subject. For example, the artist may define and store a recipe requiring that a template with three window openings have a main subject face in a larger left window and low color non-face and non-main subject in the two smaller windows to the right. Image segmentation algorithms provided on the computer system along with people or main subject detection algorithms are oftentimes adequate to fulfill aesthetic image splitting requirements depending upon the artist's template recipe. A more advanced splitting technique uses seam carving as described by A. Shai, S. Ariel in “Seam Carving for Content-Aware Image Resizing”, ACM Transactions on Graphics, Vol. 26, Issue 3, July 2007, to determine low energy regions of the image. This document is incorporated by reference herein in its entirety. These low energy regions are ideal candidates for splitting and can significantly aid the creative designer to define template recipes for attractive coordinated image displays.

Stored template recipe files created in advance by an artist can apply to the overall image enhanceable item 300, as well as for each window opening within the item. Each window recipe file can be combined and stored with other window recipe files to generate a stored template recipe file. These recipes can be designed and executed on the computer system for determining parameters such as, but not limited to, landscape vs. portrait orientation, colorfulness, sepia, color tint, person, face, main subject, size of person/face/main subject, location of person/face/main subject, surrounding regions of person/face/main subject.

In a preferred embodiment of the present invention, in order to size objects correctly, a relative measurement algorithm is used. This programmed system can specify size and location of an object in an image via a variable measure called a unit. A unit can be defined as the width or height of a face, the width or height of a main subject, or the width or height of an object in the image. A window recipe file can specify requirements to fill a window with a single person, that a face is 20% fill; where face location is specified as two unit spacings from a left edge, one unit spacing from a top edge; where there is low texture in the area of the image including two units of spacing to the right of the face or main subject; where the colorfulness of the person's shirt/blouse/dress (at 2 units below face) is high. The capability to specify and store in the computer system these required image attributes as window recipes for later repeatable use provides extensive creative flexibility for an artist.

In another preferred embodiment of the present invention, images can be scored on a merit system. The image that scores highest for a particular window recipe is indicated as assigned to the corresponding window. This can be programmed to occur automatically upon activating an application on the computer system, provided that there is a number of computer accessible images available, with no user interaction. This frees the user from the laborious and time consuming task of looking through many image files and is able to automatically create an image enhanceable item 300 that is often much superior to what a lay user could create because the designed look was created by a skilled artist. Of course, if the user is not happy with the automatic selection of templates and images, he/she can manually override the system, by selecting a user control option provided by the program, and either rescale, replace, re-crop, re-enhance, or modify an image using various off-the-shelf software products for digital image editing, or designate a different image from his or her collection of images for a particular virtual template window opening.

An exemplary recipe for a window, which can be one of a plurality of windows in an image template, is illustrated by the following code segment:

<MetaDatum Label=“EastmanKodakCompany” Tag=“Orientation” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“OrientationWeight” Datum=“20” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FacialCloseToNum” Datum=“3” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ FacialCloseToNumWeight” Datum=“10” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Favorite” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FavoriteWeight” Datum=“10” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Resolution” Datum=“2431800” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ResolutionWeight” Datum=“100” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“OffsetLeft” Datum=“1” />

In the above recipe, each required image attribute entry is delineated by brackets and, where appropriate, is followed by an entry defining its weighting factor. In the first line, Orientation is the image required attribute, and the value paired up with Orientation key is the value 1, which in this example represents landscape orientation (“0” indicates a portrait orientation). Thus, landscape images will receive an attribute score of 1, portrait images a score of 0. For this example and the others that follow below, the ordering of the entries is arbitrary. The weighting factor is used for scoring images as is explained below.

The FacialCloseToNum required image attribute indicates that the input image should contain close to three faces according to its value. An image with exactly three faces would receive a score of 1. Images with 2 or 4 images receive a score of 0.5, images with 1 or 5 images receive a score of 0.25, images with zero faces receive a score of 0, images with 6 images receive a score of 0.125, images with 7 or more images receive a score that can be calculated by score=1/(2̂(ActualFaces-DesiredFaces)), where DesiredFaces is the Datum value of 3 in the FacialCloseToNum attribute line. Similar attribute tags can be programmed, using any range of assigned values or by applying various value formulas, for FacialNumExact (an exact number of faces in an image), FacialGreaterThanEqualToNum (for a minimum number of faces in an image), and FaeialLessThanEqualToNum (for a maximum number of faces in an image).

The Favorite tag defines whether the required image attribute indicates using one or more of a user's designated favorite image or images. Favorite images will get a value of 1, non-favorite images will get a value of 0. Of course, other value assignment strategies can be programmed into any window or template recipe.

The resolution tag defines a resolution based on pixels required for the image in the corresponding window. In this case, the image is required to have an image attribute resolution of 2431800 pixels (computed as (width in pixels)×(height in pixels)) or higher to obtain the resolution weight added to its overall score. Images with total number of pixels>=the Datum attribute receive a value of 1, all other images receive a value of 0.

The weighting factor as used for required image attributes enables the artist to specify a different level of importance for each required image attribute when determining the image's overall score. The weighting factor multiplied by the image attribute score generates a weighted score for each attribute. The sum of all weighted scores gives a total score for each image evaluated by this computation method. Clearly, various procedures for determining compatibility of images with required attributes can be devised and easily programmed for use with this embodiment of the invention. The image with the highest total score is the image that most satisfies, or is most compatible, with the window recipe. In a preferred embodiment of the present invention, if a weight line is omitted for a particular attribute, the default weight of 10 is automatically assigned. Attributes which are more important have weights greater than 10, and attributes which are less important have weights less than 10. If an attribute is mandatory, a weight of 100 (or higher) is assigned. As used herein to modify the term “attribute(s)”, the terms “required” and “requirements”, etc., are variable requirements according to the weights ascribed to any particular attribute. Thus, an attribute rises to the level of “mandatory” if its weight is programmed with a value of 100. For example, in the above code segment, the ResolutionWeight is equal to 100. This means that only images with 2431800 pixels or higher can be used in this window opening.

All entries, except the last one in the above example recipe segment, are used for scoring candidate images. The last entry, in this example it's “OffsetLeft”, is used as a template/window specification, and not as an image selection guideline, and thus the last line does not have a paired weight line. The last entry specifies that the highest scoring image, or the image selected for a virtual template opening, should be modified in some respect. This can be referred to as a “post processing” step because it is used as a fine tuning step or as a post-selection layout step. In this example the specification states that the main subject be shifted left using the rule of thirds before virtual placement into the template opening. The rule of thirds is a photographic composition rule that has proven to yield well balanced or natural looking prints by the average observer, and can be programmed for use by computer system 26. If an image is broken into an equally spaced 3×3 grid with two horizontal and two vertical lines, the aesthetic design idea is to move or place the image such that the subject of interest is located on one of the four dividing lines. Similar rule of thirds tag entries include “OffsetRight”, “OffsetTop”, “OffsetBottom”, “OffsetUL”, “OffsetUR”, “OffsetLL”, and “OffsetLR” to place (or move) the image such that the main subject is located on one of the four rule of thirds lines or, as in the last four examples above, on one of the four intersecting points of these lines. Other template specification tag entries, for post-selection layout, exist to modify a specific main subject/face size and location, or overall image rendition, such as “sepia”, “B/W”, “colorful”, “light”, “high Contrast”, “soft”, “cartoonization”, “emboss”, and other artistic or aesthetic effects.

In another preferred embodiment of the present invention, favorite or primary images can be designated as such in an images recorded metadata and used as either the focal point of the image enhanceable product, can be tagged for special or unique treatment either at pre- or pos-selection, or can be used as a primary template image such that images in other template windows must conform, as defined in their associated required image attributes, in some aspect to key characteristics of one or more image attributes of favorite or primary images. For example, a large window opening in the center of a template might be appropriate to place one of the customer's primary images. Such an opening can be designated as a primary opening in a template and its required image attributes can be defined such that it will receive an image designated as primary or favorite. A user of the computer system can be programmably prompted to identify such images during operation of computer system 26 or such images might have a “primary” indication already stored in association with the image as a recorded metadata tag. Other template openings can also be designated as primary, or as secondary, etc., and image files can include metadata information indicating which ones are favorite or primary images so that the programmed computer system can search and find these images for placement into the designated template window. As mentioned earlier, a customer can designate an image as a primary or favorite image, can dictate the location of their favorite image within one of a number of template windows, or may tag many images as favorites, letting the program automatically pick from a selection of favorite images using other image attributes as selection criteria based on required image attributes defined in template or window recipes. Other images in neighboring template openings can then be automatically selected by computer programming according to window recipes stored in association therewith. Other features of window recipes can include detected similar color and tone characteristics, or other stored image aspects, of the particular favorite image or images.

For the example recipe defined by the program segment above, an image would be required to have the following image attributes: it would have to be designated as a favorite image, be laid out in landscape mode, be a group shot, optimally with 3 people in it, and needs to have a resolution of 2431800 pixels or higher to obtain the perfect total score of 40 in this example (the resolution weight of “100” is not an actual weight because the number “100” triggers a special case handling in the program that the resolution weight is mandatory, and not just a relative level of a requirement). The total score is obtained by evaluating each attribute independently, then summing together each image's weighted values. Also in this recipe example, as dictated by the attribute weights, aspect ratio, with a weight of 20 is more important to the artist than most of the other scoring attributes which each have a weight of 10.

The above required image attribute values and weights (in XML these are referred to as key value pairs) are designed by the artist and are stored in computer storage or memory 40 as definition files for each template opening (i.e. “window recipe”) as a method to realize the artist's aesthetic intent. In addition to defining attributes on a window by window basis, openings can be referenced by a group name, or template name, where all window openings in a named group, or template, have at least one common attribute (i.e. “template recipe”). In addition, a grouping of all openings in a template can be programmed for enabling global required image attributes, where such attributes are required for all openings in the template. A precedence procedure can also be programmably defined, for example: required image attributes for a group of openings supersede global required image attributes, and individual opening required image attributes supersede group attributes. For example, the artist may define a global required image attribute requiring that all openings must contain people by specifying under the global recipe:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“FacialGreaterThanEqualToNum” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FacialGreaterThanEqualToNumWeight” Datum=“100” />

By weighting such an attribute with a value of 100, it becomes mandatory. Therefore, if there are no satisfactory images found after performing an automatic programmed search through available image data bases the program may notify the user that it can't be fulfilled. In the above global attribute example, if a weight were not explicitly specified, a default weight of 10 is automatically assigned in a preferred embodiment. Subsequent examples herein will not specify weight values for purposes of simplicity of description.

In another preferred embodiment, a window recipe might define required image attributes such that each window includes an image having a particular time-date stamp, GPS location, camera parameters, or other user definable tags. For example, a window recipe can include any combination of the following example required image attributes:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“DateMin” Datum=“10/20/2008” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“TimeMax” Datum=“21:00” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Date” Datum=“10/20/2008” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“GPS” Datum=“(44.613934, −110.558167)” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“GPSRadius” Datum=“75.5m” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ISO” Datum=“400” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Title” Datum=“Disney” />

The first two examples above define the minimum and maximum date and time of capture of the image. DateMax and TimeMin similarly exist. In the above example for DateMin, the full month/day/year is specified. This format can be changed to any of a number of accepted formats like day/month/year. It is also acceptable to include partial dates. If the day of the month is to be omitted, the above Datum would be “10//2008”. The third example shows an example of specifying an exact date. A similar field exists for Time. In addition to specifying an exact date as above, well known holidays can be substituted, such as Datum=“Thanksgiving”, or Datum=“Memorial Day”. Similar substitutions of “Noon” and “Midnight” can be used for the time entry. The fourth and fifth examples require the image to be captured at a particular GPS location, such as a campground near a particular tourist attraction (within 75.5 meters in this example) in Yellowstone National Park; the fifth example allows control over the camera's image capture conditions such as ISO, and can be used to specify more advanced features such as focus distance, F#, etc. The final example can be used to require images with particular customer or third party provided metadata tags. In this example, recorded metadata associated with an image is required to include the text “Disney”. For another example, it is possible for a user to specify for a window recipe only shots of “Uncle Joe”, or for a Kiosk application to require looking for images on a particular website that are metadata tagged for specific usage on a particular template or a particular family of templates. For example, the program can be designed to look for images tagged with “Uncle Joe” on the user's or users friend's Facebook account, and such an account on a computer system accessible web server can automatically be searched and images having the required metadata retrieved; or images from Flickr that are tagged as “sunset” can be required in a window recipe; or custom databases can be created locally on the computer system or on a coupled computer system in a distributed network, or on network accessible servers with the intention of combining images stored in them into user enhanceable products.

Public or private image databases may have tagged images with specific content available for usage in the user enhanceable product 300. This content may be generic such as “beach”, “palm trees”, or may have a unique identifier with a product label such as “Kodak Premium”, or may be authorized by and associated with a particular celebrity such as a “Famous Designer”, or may be part of a special store promotion such as “Walmart Summer 2008”. More than one Title recipe entry can exist to tag a window opening, for example “Famous Designer Fall 2008 Collection” or “Colorful Leaves” is required to appear together with “Disney”. The usage of such template recipes can be used to entice consumers to purchase the latest celebrity branded and celebrity approved image enhanceable item 300 and may include the automatic diversion of royalties to said entity and entice the return of customers time and time again to purchase the latest offering by a specific celebrity/artist/sports/famous person or event such as a World Series 2009 collection.

Once again, the programming of global recipes and local recipes for each window can be used to generate recipes for templates of various types. For example, when creating a picture book, it is often desirable, but not mandatory, to arrange pictures in chronological order. We can create global recipe for a picture book template to “softly” enforce such rules for each window in the virtual picture book template, as shown below, by assigning a lower weight values for “soft” enforcement:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“Date” Datum=“W1>=W0” />

In the above example, the recipe requires that W1 (window 1) should have a date (or time stamp) that is greater than or equal to W0 (window 0), a greater time stamp meaning later in time, where W1 and W0 are more generally described as W<integer>, where integer is any window opening ID. By modifying the assigned weight of the above recipe, we can enforce more or less the desire to maintain a chronological ordering of customer images in a picture book as compared to other image attributes. To force chronological ordering as a mandatory entry, the weights would be set to 100 for this entry for each window opening.

In another preferred embodiment of the present invention, the window recipe might include color intent such that each window opening in a template has a defined stored color intent. For example, a recipe can control color content as follows:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“ColorIntent” Datum=“Cool” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ColorIntent” Datum=“Cyan” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ColorIntent” Datum=“150,220,75” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ColorIntent” Datum=“W0” />

The first entry defines the required color attribute via values such as “warm” and “cool” for the image; the second entry defines the allowable color attributes via specific color values as “red”, “green”, “blue”; the third example defines the allowable color attributes via specific 24-bit RGB code values to define required image attributes with a specific color value to match, for example, a company logo, pantone color, or other pre-defined color scheme. The final line is the most complex: if the attribute value (Datum) is a W<integer>, this indicates that the primary color from an image disposed in window opening <integer> is first to be extracted, and then the current window opening is defined to require image attributes to have primary colors similar to, or dependent upon, that of the image in window <integer>.

In the previous examples, images that have attributes as defined in the required image attributes score higher than those that do not. After the best image is selected, the image is further modified to accommodate the window recipe command. So, for the last example, if W0 had a warm primary color, the image that matches this warm color the closest gets the highest weight. Upon final selection of an image, the image selected for this window opening is further checked and modified, i.e. colors are modified to warm properties, if necessary, to obtain this same warm primary color from window W0.

In another preferred embodiment embodiment of the present invention, the window recipe might include tonescale intent such that images in each window opening in a template has a predetermined tonescale. For example, each recipe entry line can control tonescale in any of the following ways:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“ToneIntent” Datum=“Light” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ToneIntent” Datum=“Low” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ToneIntent” Datum=“W0” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ToneIntent” Datum=“~W0” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ToneIntent” Datum=“W0|W1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ToneIntent” Datum=“~(W0|W1)” />

The first example controls the allowable image scene contrast attributes via values such as “light” and “dark”; the second example controls the allowable image contrast intent via specific attribute values such as ‘high, “low”, or “normal”. The next example is similar to the color intent. If the required image attribute value is defined as W<integer>, this indicates that the primary tonescale characteristics from an image in window opening <integer> is first to be extracted, and then the required image attributes for an image in a current window is chosen to have a tonescale similar to, or dependent upon, that of an image in window <integer>. This feature can be used in conjunction with or independently from the designation of a favorite image, where the color/tone information is extracted from the favorite image and used in other window openings to define required image attributes. This is a powerful program extension, for example, that would allow, for example, the color and tone of all images in a template to match a certain reference image. The certain reference image might or might not be included in the template. The reference image might be of a paint swatch, fabric, or an image of a room or any other item.

This recipe type can also be used in other commercial applications. For example, a window recipe can be created for a school yearbook whereby each graduate picture is a window having defined required image attributes associated therewith, and the color and tone of each picture be made to match, or be compatible with, a reference image. Similar applications exist for advertising. A mail order catalog or weekly store circular can use window recipes to describe page layouts such that all or a group of images have similar contrast. A programmable storefront display can be advantaged with similar required image attribute designs.

In the third example, if the required attribute value is ˜W<integer>, this indicates that the primary color/tone characteristics from an image in window opening <integer> is first to be extracted, and then the current window opening is chosen to include am image having a color/tone opposite to that of the image in window <integer>. So, if the window <integer> image is high contrast, the current window opening will have an image with low contrast. Accordingly, the higher the contrast in window <integer> image, the lower the contrast in the current window image.

If the attribute value is (W<integer1>|W<integer2>| . . . | W<integern>), this indicates that the primary color/tone characteristics from images in windows <integer1> . . . <integern> are first to be extracted, and then the required image characteristics in the current window opening is chosen to have a color/tone similar to the average of the images in the n window openings. Similarly, if attribute tag value is ˜(W<integer1>|W<integer2>| . . . |W<integern>), this indicates that the primary color/tone characteristics from images in window openings <integer1> . . . <integern> are first to be extracted, and then the current window opening is chosen to have an image with color/tone opposite to the average of the n window openings.

Using the color and tonescale required image attribute values, the artist can design all window openings to have similar color/tone content, unique color/tone content, or some combination thereof. It should be readily understandable that these two examples can be modified to include other required image attributes such as texture, colorfulness, season, time of year, time of day, people, sharpness, and noise.

In situations where a customer manually adjusts the color/tone/sharpness/cropping of an image in a window opening via the user control option that affects the color/tone/sharpness/cropping of another window in the project whose required image attributes are dependent upon such characteristics of the image, the dependent image can be programmed to be automatically adjusted accordingly. For example, if window opening W5 is defined to have an image with identical contrast as the image in W1, and the user then manually adjusts the contrast of the image in W1, making it higher, the contrast of the image in window opening W5 will also increase automatically according to the program. In some situations, the user may choose not to activate this feature, so the user control option can be configured accordingly.

In another preferred embodiment of the present invention, the window recipe might include further object detection or scene reflection required attributes. For example, the window recipe can dictate more specific requirements for each window opening:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“Object” Datum=“Balloon” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Theme” Datum=“Fall” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Similar” Datum=“W1” />

The first example controls whether the window opening should have a specific object in the scene (a balloon), and can also specify other objects such as “BirthdayCake”, “SoccerB all”, or “Dog”. The second example controls a required attribute defining a theme for the opening with a value such as “city”, “colorful”, or “dreamy”. The former example can be used to search for and select all images from a soccer game or a birthday party. The latter example can be used to define a proper mood for a particular window opening. The last line utilizes a similarity measure between images. It defines the image in the current opening to be similar to that of Window opening 1. This feature supports the ‘˜’ attribute which indicates “dissimilarity” in images, and the ‘|’ feature which indicates averaging several windows together. The similarity measure can use any number of image attributes, but RGB histogram statistics such as Chi-squared analysis or low resolution pixel correlation metrics can also be used, are fast, and perform quite well. Two low resolution metrics that perform well are Mahalanobis distance and edge map correlation. The Mahalanobis distance is similar to standard deviation, but also takes into consideration the correlation between each of the individual color channels. The edge map correlation is performed on low resolution images (64×96 pixels or smaller) by comparing the derivative (using Sobel filter) of the reference image to the derivative of all other images. More complex similarity metrics which utilize complex semantic information can be readily incorporated.

In another preferred embodiment of the present invention, the recipe can include further object, and scene attributes, such as in the following examples:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“Location” Datum=“Beach” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“SceneContains” Datum=“Snow” />

The top example controls the ability to specify a generic location required attribute value such as “water”, “beach”, “city”, or “indoors”. These locations are overall scene classifications, and the resulting classification is based on an output from a scene classifying computation carried out on a digital image. The last example can further constrain the image selection procedure by requiring that scenes in an image contain certain objects or characteristics such as “snow”, “water”, “sky”, “foliage”, “dirt”, and “skin”. The latter example can be implemented via belief maps. If no snow is found in an image, a value of 0 is returned as that image's attribute value for “snow”. The more snow found (the greater the percentage of snow pixels), the higher is its corresponding value for the required “snow” attribute in the window recipe. A discussion of sky detection is provided in Gallagher, et al., “Detection of Sky in Digital Color Images”, U.S. Pat. No. 7,336,819 and an example of foliage detection is provided in “Color Segmentation as an Aid to White Balancing for Digital Still Cameras”, by Cooper, Proceedings of SPIE, v4300, p 164-171, 2001. Both of these references are incorporated herein by reference in their entirety.

In another preferred embodiment of the present invention, the recipe can include further people attributes, such as in the following examples:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“AgeLessThanEqualtoNum”‘ Datum=“2” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FacialPose” Datum=“Left” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FacialEpression” Datum=“Angry” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“EyesOpen” Datum=“1” />

The first example attribute requires that the age of people depicted in the image be less than or equal to a certain number, in this example less than or equal to two years old. Similar attribute requirements exist for AgeGreaterThanEqualtoNum, and AgeClosetoNum. Often we want people facing “forward”, but, it is often desirable for a person or persons pictured in one window to be looking in the direction of a second window opening. The second example requires a particular facial pose of people or a person depicted in the image, in this example the person should be looking left. The next example above indicates a preference for a facial expression or demeanor. This allows control over facial expressions such as “angry”, “sad”, “surprised”, “happy”, “smile”, and “neutral”. The last example can be used to make sure the eyes of all found faces are open. Similar tags can be written to control related features such as ethnicity, gender, hair color/style, eye color, skin tone, height, age, facial or hair accessories (sunglasses, headband), facial hair, and mouth open/closed. These controls are well known algorithms familiar to persons of skill in the art, and are similar to those previously disclosed.

The next example utilizes facial recognition to identify a person in an image.

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“PersonID” Datum=“Uncle Joe” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“PersonID” Datum“W0” />

In the first example, the required personID attribute controls which person's image is being inserted into an opening. The attribute value “Uncle Joe” can be satisfied either by searching for and finding recorded metadata associated with the image, or by utilizing an accompanying facial recognition database and extracting the metadata. It is well known that extracted metadata can thereafter be recorded with the image and need not be obtained by repeating the extraction processing later. Many cameras and imaging software packages now include facial recognition capabilities. The last example above utilizes the window relationship feature for window recipes. This last example says that the image being placed into the current opening must have a person, and that person must also be in window W0. This last example is a generic way of describing a relationship of people appearing in more than one template window. For example, we can have a center template window contain a closeup of a single person as dictated by a favorite image being placed therein, and all surrounding template windows may thereby be defined to require that same person somewhere in the image.

In another preferred embodiment of the present invention, the recipe can include further image selection steps, such as in the following examples:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“AspectRatio” Datum=“1.5” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“WindowShape” Datum=“Oval” />

The first example attribute defines the window opening width over height aspect ratio. In this case, we know the width is 1.5 times the height. When used together with the second example, defining an oval, we can define a maskable area to overlay on top of any candidate images. We then use the maskable area to score each of the candidate images. WindowShapes can include Rectangle, Circles, Ovals, Pentagrams, Hexagons, RoundedCornerRectangles, and can be easily extended to any other shape. When AspectRatio and WindowShape are used in combination with other recipe items such as PersonID, FacesClose2Num, etc, only the maskable area is included in the overall score. For example, a 1.5 aspect ratio rectangle may include 5 faces, while a 1.5 aspect ratio oval may only include 3 faces and would result in different scores for the same underlying image.

In another preferred embodiment of the present invention, the recipe can include multiple image selections per window opening. This is defined as having two or more recipe entries for each window. In the case of overlap, the last recipe entry is the top entry unless the Order entry is used. For example, we may have the following two examples for a single window opening:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“AspectRatio” Datum=“0.5” /> <MetaDatum Label =“ EastmanKodakCompany ” Tag=“WindowShape” Datum=“Oval” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“PersonID” Datum=“Uncle Joe” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“PersonID” Datum=“Aunt Suzie” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FacialEqualToNum” Datum=“2” /> Along with the following second recipe for the same window opening:

<MetaDatum Label =“ EastmanKodakCompany ” Tag=“AspectRatio” Datum=“0.5” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“WindowShape” Datum=“InverseOval” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FacialEqualToNum” Datum=“0” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Location” Datum=“Sand” />

The first recipe specifies an oval mask, half as wide as tall. We want exactly two people, Uncle Joe and Aunt Suzie. The second recipe also specifies an oval mask, half as wide as tall, but, it is an inverse mask. So, the image area outside of the oval is used for image scoring. In this case, the second image outer mask area image should have no people and contain sand.

The above two examples assume the image is centered and fills the window opening as much as possible. It is possible to do various collage type entries for each opening, by specifying the subwindow [X,Y] offset and the subwindow width and height for each of the recipes that fulfill a particular opening.

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“SubWindowX” Datum=“0” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ SubWindowY” Datum=“0.5” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“SubWindowW” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“SubWindowH” Datum=“0.5” />

In the above example, the image that scores highest for this particular recipe will be fit to the lower half of the window opening. Values for SubWindowX, SubWindowY, SubWindowW, and SubWindowH scale between 0 to 1.0, where (0,0) is the upper left corner and (1,1) is the lower right corner, but other conventions can be used. Finally, these subwindows can be feathered into one another and order can be assigned as follows:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“Feather” Datum=“0.1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ Order” Datum=“0.75” />

In the above example, feather command controls the feathered edges on an image. The convention used here is that the feather value can be any percentage of the window opening width. The Order value assigned a floating point hierarchy to each image in a window opening, where higher values move the window further to the front. If no Order value is specifically stated, or if we have two identical Order entries, it is assumed the order of the current recipe is in front of the previously found recipe for the same window opening. If the first recipe per window opening does not have an Order value, a default of 0 is used, which means it will be in the back, and all other images will be placed in front of it. Using masks, inverse, masks, locations, and order enable a powerful scripting language for the skilled artist.

In another preferred embodiment of the present invention, the recipe can include the demarcation of specific regions of the image. In particular, region segmentation of sky, snow, skin, foliage is often determined by color and location within the image. Background areas are often denoted by lack of texture. These regions can automatically be masked off and combined or replaced with other attribute areas:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“SelectSkyInverse” Datum=“0” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“SelectFace” Datum=“50” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“BackgroundColor” Datum=“W0” />

The first example can be used to set the transparency of the non-sky region of the selected image to 0%, or set the transparency of the sky to 100%. The Datum value indicates the transparency value. When this image is overlaid on top of a previously fulfilled recipe for the same window opening, the sky will be replaced with the image contents of the background image. When the Select tags are used, all areas not included are set to a transparency of 100, such that they will not be seen in the reproduced image. In the second example, we are selecting just the facial region of an image, the rest of the image will be transparent. The face will have a 50% transparency, such that it will be blended with the existing background image at 50%. When used with SelectFaceInverse of a second image, we can swap the face of one person with another. The results of the face swap are much better if the exact facial outline is selected using one of the previously mentioned examples. Finally, in the last example, the background of an image is selected based upon image energy, where energy is described by Avidan and Shamir in “Seam Carving for Content-Aware Image Resizing” in ACM, Vol. 26, No. 3, July 2007, incorporated by reference herein in its entirety. The low energy area is considered background area, and in this case, the color of the background area will be made to match the primary color of what was in window opening 0.

The first example can be used to create adaptive montages of either aesthetic or practical significance. Aesthetically, special effects can be created, for example, in an advertising poster to add an image or text in a sky or background area of an image. The second example can also be used to create artistic effects, but can also be used to replace faces that have inappropriate facial expressions, eye closers, head pose, etc, with faces that are more appropriate. The second example can also be used in commercial purposes to replace, for example all the heads of models in the store circular with the children in ones family. A custom softcopy circular can be created for each household, not only with custom targeted content, but with family members wearing the clothing, operating equipment, or looking on in the distance. Social websites like Facebook can use such recipes to create custom slideshows for both pleasure and profit. The latter example can be used in context with the previously described adaptive recipes such that the end product more closely follows a theme or more closely resembles the artists intent. For example, the background information can be made to have the texture or color of a favorite image, made transparent or just driven to white so that the window opening can concentrate on the main subject.

In another preferred embodiment of the present invention, the recipe can include the usage of units in window recipes to specify the size and location of a particular face, main subject, or other object. For example:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“FacialEqualToNum” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FacialEqualToNumWeight” Datum=“100” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FaceSize” Datum=“0.5” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FaceLocation” Datum=“Center” />

The first recipe line defines the current window required image attribute needs an image with one face. The second line says this required image attribute is mandatory—it is mandatory for the image to have exactly one face. Images containing 0 or greater than 1 face are not considered for inclusion in the current window opening. If no images with exactly one face are found, the recipe cannot be fulfilled, and (as with all other unfulfilled mandatory required image attributes) the job can be terminated, a notification can be provided to the user, an option to override the requirement can be provided, or an option for the user to insert a selected image can be provided, or the user can be prompted for some other type of intervention. The third line defines that this face must occupy 50% of the image area. Images with slightly smaller or larger faces will score high, images with large face differences will score lower. One formula used is 1−abs(TargetFaceSize−ActualFaceSize), but non-linear variants such as logarithmic, gamma, and similar functions can also be incorporated. Regardless of the preferred variations for evaluation, an image with one face, covering closest to 50% of the window area will be calculated to score the highest and be selected for inclusion in the template window. After selection, the image can be specified for post-processing and be resampled such that the face will occupy exactly 50% of the window area. The final line above specifies to center the face in the middle of the window opening. The FaceSize and FaceLocation key value pairs include the W0 and similar options such that the size and location of faces can mimic that of the favorite images placed in the template. In addition, because sizing is so critical, the FaceSize and FaceLocation key value pairs include the more advanced W0 notation, such as:

Tag=“FaceSize” Datum=“W0*0.8” /> <MetaDatum Label=“ EastmanKodakCompany ”

This defines, for a window recipe, that the face in the current window opening should be 80% of the size of the face in window opening W0. When multiple faces occur, the FaceSize and Location refer to the average face size and centroid of all faces. When W0|W1|W2 notation is used, it defines using an average size face from window openings W0, W1, and W2.

In addition to “Center”, FaceLocation can include the rule of third locations, UpperLeft, UpperRight, LowerLeft, LowerRight, as well as Upper, Lower, Left, Right. The W0 notation for FaceLocation includes mirroring the location such as:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“FaceLocation” Datum=“W0*HorizMirror” />

The above recipe line will mimic the horizontal location of the face—so if the face in W0 was in the upper third, the face in the current window would occur in the lower third of the image. To make relative locations as compared to W0, offsets are used such as:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“FaceLocation” Datum=“W0+0.2H−0.3V” />

Where the above line says the face location in the current window should be the same as the face in window W0, but, should be offset 20% to the right and 30% towards the bottom. The above commands are illustrated for use in detected faces, but equivalent commands exist for main subject size and location as well as object size and location when the main subject is something besides a face.

The process of evaluating the fitness, or compatibility, of multiple images as against a window recipe for a particular window is shown in FIGS. 4-6. FIG. 4 shows a window recipe for a window in a user enhanceable product, such as a picture frame. The required image attributes include: a favorite image with weight 20; contain 2 faces with weight 40; contain frontal pose with weight 20; and be indoors. The last two lines in FIG. 4 are used as a template/window specification for post selection layout, and not as an image selection guideline, and thus the last two lines do not have a paired weight line. Optionally, a user would then select their favorite image or images to be placed in prominent windows or other locations in the virtual template. FIG. 6 illustrates an example group of searchable images. There are n images displayed on the left. Each image's fitness will be evaluated according to the window recipe in FIG. 4. For the sake of simplicity, we will assume that the user has preselected image2, 620 and imagen, 640 as their favorites.

FIG. 5 shows the method of evaluation computation of each required image attribute for each image attribute. For each image attribute, we have a value, which is determined either by a metadata entry or semantic algorithm. This value is between 0 and 1.0, where 0 is the lowest possible score, and 1.0 is the highest possible score. After multiplying by the accompanying attribute weight, a resulting weighted value for each required attribute per image is obtained. After summing up all weighted values for each image, a total image score is obtained. The image with the highest total score is the closest compatibility match to the recipe.

The first listed attribute is for favorite images. 620 and 640 receive a value of 1. 610 and 630 receive a value of 0. Multiplying by the favorite weight of 20, we get weighted values of 0, 20, 0, 20, respectively, for each of the four images shown.

The FacialCloseToNum attribute favors images with 2 faces. Unfortunately, none of the images have two faces—each image having one too many, or one too few faces, giving a value of 0.5 for each image. Since the FacialCloseToNum weight was 40, multiplying 40 and 0.5 results in a weighted value of 20 for all four images.

The FacialPose attribute favors all frontal poses. Facial pose estimators return the pitch and yaw of a face in degrees. The value is calculated by setting value=(100−(Pitch+Yaw))/100, and then clipping such that the value calculation is normalized from 0 to 1.0. This strongly favors frontal poses where pitch=yaw=0, and penalizes poses otherwise.

The Location attribute is looking for indoor scenes. State of the art indoor/outdoor locators use metadata tags of ISO, exposure time, and flash fire, along with key semantic information such as foliage and sky colored pixels, along with overall color temperature of the scene. The returned value is an estimate that the scene is indeed an outdoor scene. For scenes 1,2,3,n, the value returned was 1, 0.7, 0.25, and 1, yielding weighted values of 9, 7, 2.5, and 10.

With the evaluation of the above weighted values for each image and attribute completed, we sum the weighted values for each image, giving a total of 49, 67, 42.5, and 55 for images 1, 2, 3, and n and assign to 615, 625, 635, and 645 in FIG. 6. 67 is the highest total score, corresponding to image 620. Image 620 satisfies the window recipe illustrated in FIG. 4 the best and is selected 650 for inclusion in the window opening.

The last two lines of the recipe in FIG. 4 provide post-processing instructions for image 650. The Offset UR says the face in the image should be located in the upper right rule of thirds intersection. The FaceFill attribute indicates that the size of the face should be 20% of the width of the window opening. The above two rules are shown schematically, 660 in FIG. 6, along with the final image, 670.

Additional post-processing instructions can be utilized to change the color, tone, sharpness of images and change the relative color, tone, contrast to other window openings as follows:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“AutoEnhance” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Contrast” Datum=“<W0” />

Where the first example defines applying an autofix or automatic image enhancement to the image in the current window. Similar entries exist for AutoNeutralBalance, AutoColorBalance, AutoContrast, Auto Sharpness, and AutoZoomCrop. If AutoZoomCrop is used, and the window opening still scores highly if small, outlier faces are automatically cropped out of the image, they will be cropped out as long as the resulting image resolution is sufficient for the final enhanceable product. The second example indicates that the contrast of the image in the current window should be less than the contrast than the image in window 0. Similar entries exist for Colorfulness, Brightness, and Sharpness. In addition, the Datum values of “>W0” would mean the criteria in question would be greater than window 0; and “>>W0” would indicate the criteria in question would be much greater than window 0.

The concept of using the > and < characters in the recipe also allow relative specification of window content. For example:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“AgeClosetoNum”` Datum=“>W0” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“AgeClosetoNum”` Datum=“>(W0+10)” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“AgeClosetoNum”` Datum=“<(W0+30)” />

Where the first example defines having the current window contain a person whose age is greater than the estimated age of the person in window 0. If >> was used, the age would have to be much greater. These relative relations can be easily defined within the program as desired, for example, “>” could be defined as five years, and “>>” could be defined as fifteen or twenty years. The next two examples show how to specify the age of the person in the current window to be between 10 and 30 years the estimated age of the person in window 0. The addition of >, >>, <, and << along with the offsets, |(averaging), and ˜(inverting) enable a rich suite of tools for the artist.

The described embodiments of the present invention are not limited to the values and attributes defined herein, and can be extended to other parameters as an artist sees fit. As computer and hand held device algorithms evolve, future available image metadata can be incorporated. While some metadata tags are easy to evaluate, such as time stamp, others are more complex, such as selecting images with balloons. As the recipe is loaded into the program, a list of necessary attributes is accumulated, and only those attributes that are required for a particular image enhanceable item 300 are resolved for each image.

Another preferred embodiment of the present invention is the usage of adaptive recipes. For example, a user is making over a room in his home and would like to hang decorative image enhanced items on the wall. The user can bring a paint sample from the room to a retail kiosk that is running a computer system program embodiment of the present invention such as on computer system 26, and the paint sample can be scanned by the kiosk's flatbed scanner 38. This paint sample can be used to define overall color and texture required image attributes for the decorative image enhanceable wall hanging. Similarly, a frame matte can be scanned for defining attributes such as color and texture. If a flatbed scanner is not available to kiosk computer system 26, a calibrated webcam or video camera at a kiosk will suffice. Similar techniques can be used if a user brings in a swatch of material, such as a pillow, cushion, curtain, or any other object in the room to be decorated. Not only can the resultant user enhanceable product be made to match this material, the background matte of the template can be a replication of the actual material or paint sample. Finally, a user can take photos of objects or walls, and those objects can be used as the reference digital image. For example, a user may provide four reference materials, R0 can be a paint swatch, R1 can be a curtain, R2 can be a pillow, and R3 can be a sample from a magazine. The following window recipe examples can be applied to these samples.

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“ColorIntent” Datum=“R0” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“ToneIntent” Datum=“R1|R2” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“MattColor” Datum=“R0” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“MattTexture” Datum=“R3” />

In the first example, the color of an image in the current window can be made to match the color of R0, which is the paint swatch. This is done by first digitally balancing the image to neutral and then adding a color cast to the image—the color cast being a match to the color cast of the paint swatch. In the second example, the tonescale of the image can be similarly manipulated to match an average contrast of the curtain and pillow. In the third example, the matte color will be adjusted to match that of the paint sample. In the final example, the matte texture will be adjusted to match the texture sample from the magazine clipping. The above use of reference images is very similar to the window matching entries described above, say Datum=“W0”, but the key difference is that the reference image in these examples is not displayed in the completed coordinated image template design or in the final image enhanced product.

Another preferred embodiment of the present invention involves the evaluation of multiple window recipes on a single set of images. For example, a Famous Designer may come out with the Fall 2008 line of template recipes. Depending on the images provided by a user, one particular template recipe might be more appropriate than another. For example, if a customer loads a group of images containing sports scenes, a Famous Designer sport theme template recipe may be used initially to begin designing the final image enhanceable product. If the customer loads images of children, a Famous Designer infant or toddler theme may be selected. If a customer loads a group of images containing water scenes, a Famous Designer beach template may be chosen. The names of the template themes can also be displayed to a user so that the user can select and open a template initially whose name reflects the type of context that fits the user's image collection. The selection of a favorite image will also cause some templates to score higher than others. Based on a different selection of a favorite image, the templates that score highest can change drastically. The highest scoring template as calculated by the program can be used, or the top n highest scoring templates can be programmed to be presented to the customer for him/her to make a final decision as to which is his/her favorite template. The procedure that is followed to identify the types of scenes depicted in groups of customer images is well known in the art and is not described further.

If several favorite images are selected by the user, the corresponding highest scoring templates can be presented to the customer, or the top n templates for each favorite image can be presented, or the top n templates for only the top scoring favorite image can be presented. The types of such template recipes is virtually unlimited. Image enhanceable items 300, can include framed templates, clothing items, greeting cards, photo books, and other tangible goods; but also to softcopy goods as well such as cell phone, PDA, and computer screen savers, digital greeting cards, as well as digital picture frames, and automatic digital presentations used in store fronts, office lobbies, stadiums, theatrical shows, and for personal enjoyment.

In another preferred embodiment of the present invention, a unique template recipe is assembled on the fly and pre-selected recipes are displayed in a pre-determined or random order. For example, a continually running slide show on a digital picture frame (which can be a picture frame at home or a large electronic storefront window) may automatically extract photos from a public or private website, or from a local computer. Each and every displayed frame can be unique and can be programmed never to be shown again, if so desired. A preferred embodiment of the present invention includes a procedure of writing a continually looping program that modifies the recipe in each iteration. During each iteration, the top x compositions are displayed in a random or a predetermined order. When selecting images from online galleries such as Facebook or Flicker, or Photobucket, the number of high scoring template configurations can be staggering—and a limit can be imposed for each iteration of the looping program. The looping program can have nested loops, each changing one or more recipe entries in random or predetermined order. Fulfilled recipes can be stored in a database to prevent displaying the same recipe twice, or to purposely replay recipes in a preprogrammed or random order.

Template recipe entries can be configured by, and grouped according to, product line and can be upgradeable over time. A similar architecture can be used in many product lines, with a baseline product only offering a subset of required image attributes to be selected, a moderate product offering an extended set of selectable required image attributes, and a premium product offering a full suite of required image attributes. In addition, the attribute readers can be designed to be forward compatible by ignoring any attribute values it does not understand or can not evaluate. This can occur if, for example, a new artist's collection of templates uses attributes not recognized by a previous version of the program. For example, if balloon object extraction is not supported, it is simply ignored.

Potential designs for interpreting and using the corresponding attributes is numerous. At the highest level, a parameterized and weighted fitting algorithm scores each individual image from a set of required image attributes for each window in the template. The objective of the parameterized weighted fitting algorithm is to find the best (most appropriate) image for each window based on image/template image window required attribute comparison. As used throughout herein, a “required” opening attribute (or window attribute) is a soft or hard (depending on weights) requirement, defined in a recipe, that an image must satisfy. Image attributes are the metadata describing image characteristics that are extracted by digitally examining an image, or provided by a user, or generated by a camera, or otherwise provided and stored with an image or generated on the fly. The parameterized weighted fitting algorithm iterates through a list of windows and scores each image relative to required image attributes for a window and finds the best image for that template window.

The algorithm by which a preferred embodiment of the present invention is implemented is described in reference to FIGS. 7-12. The algorithm is implemented on a computer system such as depicted in FIGS. 1 and 2 and described above. The user interacts with the computer system via user controls 68, 58, also explained above, in response to information displayed on screen 56, 66 as performing actions requested by the user or by prompting the user for information or for making a selection. Referring to FIG. 7, the algorithm starts with presenting a template selection function 710 on display screen 56, 66. In this algorithm example and following description, we will assume that the templates presented for selection are of a form corresponding to a picture frame, as shown in FIG. 3, that the user desires to purchase. Succeeding steps of the algorithm can be implemented in well known graphical user interfaces for prompting the user for selecting options or for other information. In a preferred embodiment, the template selection displayed on the screen will physically resemble the actual picture frames available to the user for purchase. If a user has selected a mug or a tee shirt, then the displayed “virtual” template may be designed to resemble those products so that the user can see a reasonably realistic version of a desired image enhanced product that includes an image selected by the user. In the example algorithm illustrated in FIG. 7, the template options are set to default values initially at step 720. At step 705 a user selects whether he would like the system to choose a template or to participate in the template selection. If the user elects an automatic option then the system will select and store a default template at step 770 and then proceed to step 1010. If the user elects to participate then the system will display template selection options at step 730. If the user decides at this point, step 715, not to select a template then the system will revert to an automatic default template selection. If a user selects a template at step 715 the system will request the user to select template characteristics at step 740. If the user selects all requested characteristics options at step 725 then the template is complete and the next step proceeds to step 810. If the user does not provide all options at step 725, default values for unselected options are automatically stored at step 760 and the complete template specification is stored at step 780 and proceeds to step 1010.

At step 810 the template was selected by the user and now the image selection begins. If the user has not yet provided images, either in a local computer accessible database, a network accessible database or on a portable or other storage device, then at step 820 the system will prompt the use to identify where images can be accessed. The prompt may or may not occur if a data base has previously been identified to the system or if a user has coupled a portable or other image storage device to the system. If the user indicates at step 805 that he will select favorite or primary images, then at step 830 he will indicate the selected images to the system and at this point the system will automatically proceed to step 905. If the user indicates that he will not provide favorite or primary images at step 805, then the system will automatically select images based on the step as defined in block 1210. At step 840 these automatically selected images will be digitally placed into the previously selected template. At step 815 the template and selected images will be displayed to the user on a screen or monitor and the user will have the option to accept the image product, however, the present invention includes an option 860 for the user not to review the image product. If the user accepts or if the user does not review the product, the product is output at step 870. If the user does not accept the output product at step 815, then the system repeats an automatic image selection using step 1210, but outputs a template plus images that is different from any previous outputs. Alternatively, a user control option 850 can be executed at this point wherein the user performs his own selection steps instead of the step 1210 performed automatically by the computer, and the user's selection is then output at 870. The user control option can be implemented via activation of an image editing software that is part of the image enhanceable product software or it can be implemented by a separate image editing software. The output step 870 operates according to the type of image enhanceable product that the user has selected. For example, and not by way of limitation, if a frame has been selected, then the output can involve a frame with selected images being delivered to the user (home delivery or retail outlet pick-up for example), or a page with the selected images may be printed which the user can insert into an actual frame that matches the digital frame depicted on the display.

At step 905, after the user has identified favorite or primary images on the computer system, the algorithm determines if the number of primary images identified is greater then the number of openings in the template. If so, then at step 1240 a subset, equal to the number of openings, of the favorite images whose image attributes satisfy required template attributes and template opening attributes, if any, are automatically selected and then in step 910, the template, together with the subset favorite images disposed in the openings is composed, and is displayed to the user for user approval at step 915. If an option to bypass user approval 912 is active then the template and automatically selected subset of the favorite images is output at step 916. Otherwise, if the user approves the template and images, the user indicates acceptance to the computer system of the template and images as displayed and the output step 916 commences. If the user approval step results in a non-acceptance by the user then the system proceeds back to step 910 to repeat automatic image selection as described above, except that the output of the automatic image selection step will be selected to be different than any previous output. As usual, programmed preference is given to higher scoring images that best match required template opening attributes, but if the user does not accept these, then lower scoring images will be used. If user control option 914 is activated then the user has the option to specify favorite images without reactivating the automatic selection step 1240. This can be performed by presenting to the user the template with current selected images displayed therein, and an option to replace the current images with other user selected images from an image data base. The user's favorite image selections are then used in the output step 916. At this point it is an optional programming step to limit the user option to only those images that are favorites, selected at step 830, or to present the whole user's image data base for selection.

If the number of favorite images is determined not to be greater than the number or template openings at step 905, then at step 925 the computer system determines, according to the programmed algorithm, if the number of favorite images indicated by the user is equal to the number of template openings at step 925. If so, in step 1230, each favorite image is assigned the optimal window such that the overall template score is maximized, then the images are placed in said window openings in step 940, and then output step at step 946. If an optional user control step 942 is active, the template and images disposed therein are displayed to the user to enable the user to select different templates or images, or to rearrange the images displayed. After the user has completed his selections, the output step 946 is activated.

If, at step 925, the computer system determines that the number of favorite images is not equal to the number of template openings, the algorithm selects additional images to compliment the favorite images using step 1220 which is described above. At step 930 these automatically selected images will be digitally placed into the previously selected digital template. At step 935 the template and selected images will be displayed to the user on a screen or monitor and the user will have the option to accept the image product at step 935. This embodiment of the present invention includes an option 934 which, when activated, allows the user to bypass review of the image product and go directly to output step 936. If the user accepts the displayed image product, or if the review bypass occurs, the image enhanced product is output at step 936. If the user does not accept the output product as displayed at step 935, then the system repeats an automatic image selection using step 1220, but outputs a template plus images that is different from any previous outputs. Alternatively, a user control option 932 can be executed at this point wherein the user performs his own selection step instead of the step 1220 performed automatically by the computer, and the user's selection is then output at 936. The output step 936, as do each of the other output steps described above, operates according to the type of image enhanceable product that the user has selected. For example, and not by way of limitation, if a frame has been selected, then the output can involve a frame with selected images being delivered to the user (home delivery or retail outlet pick-up for example), or a page with the selected images formatted to match the template openings may be printed which the user can insert into an actual frame that matches the digital frame depicted on the display. As described above, various image enhanceable products may be produced using the inventive methods described herein and the provision of these products can be completed at the output step in a variety of ways.

Referring to FIG. 7, if the template is to be selected entirely by the system we arrive at step 770, and we arrive at step 780 if some of those template attributes are manually selected by the user. Either way, we arrive at step 1010 of FIG. 10 and the template selection or template completion algorithm begins. If the user has not yet provided images, either in a local computer accessible database, a network accessible database or on a portable or other storage device, then at step 1020 the system will prompt the use to identify where images can be accessed. The prompt may or may not occur if a data base has previously been identified to the system or if a user has coupled a portable or other image storage device to the system.

If manual mode is enabled, the user may decide, at step 1005, to manually select one or more favorite images at step 1030 which are then passed to step 1040. If manual mode is disabled, the users images are automatically selected 1040. The highest scoring template is chosen 1040 by pairing the image set with the available templates in the system. In this instance, the score is not associated solely with the template, rather, it is a score generated by compatibility computation as between image attributes and the required image attributes defined by each of the window recipes in the template recipe. If a user has selected some of the template options, these are not modified by the algorithm. If a user has picked favorite images, these images, or a subset of these images, can be required by programming to be included in the final user enhanceable product and the highest scoring template is selected based on these favorite images being included in the template. Upon completion of template selection in step 1040, if automatic mode 1060 is enabled, the final template is selected, 1070. If automatic option is not turned on, the user has the ability to override 1050 the template selection process until he or she is satisfied. Once the user is satisfied, the final template is selected 1070 and the system now needs to fill this template with images and migrates to decision 1125 in FIG. 11.

With regard to FIG. 11, the user has already been asked and optionally selected their favorite images. The template was chosen by the algorithm, or optionally overridden by manual controls by the user. All that is left to do is assemble the final product. If favorites were selected, decision 1125 then uses strategies similar to step 930 in FIG. 9, previously described. If no favorite images were selected we utilize image selection step 1210 and formatting in step 1130. If automatic mode 1150 is enabled, the final user enhanceable product is assembled, delivered, printed and/or otherwise outputted 1160. If automatic option is not turned on, the user has the ability to override 1140 the choices made by the image selection process until he or she is satisfied. Once the user is satisfied, the final user enhanceable product is assembled, delivered, printed and/or otherwise outputted 1160.

Regarding the automatic template selection process as shown in FIG. 7, further enhancements and modifications can be achieved with these embodiments of the present invention as follows. For example, each template can be evaluated across multiple criteria such as size, orientation, number of window openings, theme, color, and texture. Upon completion of the automated template selection step 1070, the template with the highest score is the template that is chosen for the user enhanceable product. As described above, all template settings are initially set to defaults at step 720. These default values can be set by the product manufacturer, individual retailer who has installed the image enhanceable product tool described herein, or by individual product line requirements. For example, it is possible to have two side by side kiosks in a store. One kiosk can be programmed with a “Famous Person” Collection version of the software described herein, while the other is a generic unbranded version. If user interactive mode 705 is disabled or if a user chooses at step 715 not to manually select a template, the default options 720 are passed at step 770 on to the automatic template selection module starting with FIG. 10 at start select images 1010.

If a user decides at step 715 to choose their own template, the user can specify the exact template by scanning a template UPC barcode corresponding to a user enhanceable product available at a retailer that has installed a compatible kiosk, or itemized menu or the user can narrow their choices using an interactive interface at step 740 to help choose all the template options. If the user does not specifically provide the exact template or does not provide all template options 725, there is still some ambiguity as to which template that will be used. In such a case, the default template options 720 are superseded by the user defined options 760 and passed 780 on to the automatic template selection module starting with FIG. 10 at start select template 1010.

If the user has provided all the template options at step 725 this results in a specific template to be used 750. We then enter the image selection phase starting at 810 in FIG. 8. If no source of input images can be automatically determined, the user is prompted for such images 820, for example, by displaying a request on a display screen, though other forms of prompting are possible, including an audible signal. If manual mode is enabled, the user may decide to manually select one or more favorite images at step 805. If manual mode is disabled, the user's primary images are automatically selected at step 1210. Before the details of automatic image selection are described, we will first describe the process of the user selecting favorite images at step 830 and the resulting program execution.

The selection of favorite images 830 involves the user previewing, for example, thumbnail size images on the display screen and marking favorite images. The user can select a number of images for n template openings in the previously selected template, where n is equal to the number of window openings in the product. For each image that is split, n is decremented by 1 for each window that the split image occupies. To simplify the description of the algorithm in this embodiment of the invention, we will assume there is no image splitting. In addition to selecting their favorite images, the user is given the option of selecting their overall favorite or primary image. If a primary image is selected, it generally will be displayed in a prominent fashion on the user enhanceable product, and other template opening required image attributes can be based upon the primary image attributes (color, sharpness, person ID, scene content, etc.).

At step 905, FIG. 9, the user has selected their n favorite images. The first decision 905 is if the number of favorite images selected is greater than the number of window openings in the user enhanceable product. If n<=m at step 905, the next decision 925 is to determine if n, the selected images, is equal to m, the number of window openings. If so, the system then automatically determines which image goes in which window opening 940.

The procedure performed at 940 is as follows. The algorithm analyzes the images and determines what attributes they have either by accessing the metadata or semantic information extracted from the image or both. Both the metadata and semantic information can be calculated and stored with the image, or in a separate file. The fitness score of each image to each window opening is calculated and then the program initializes the template by assigning the highest scoring image to each window opening. If one image has the same score on two window openings, the priority is assigned to the lowest numbered window and the image is assigned to that opening. This presumes that the windows in the template are numbered. For example, window 0 (“W0”) is stored, by default, as the highest priority window, window 1 (“W1”) is next highest, and so forth. Windows for each template can be assigned numbers internally in a template file or in a window file. If two different images score identically high in one window opening, the image can also be assigned based on metadata fields that record the number of times an image was accessed, randomly, or by another selection method. An overall sum total score for the entire template mapping is computed and is the baseline starting point score before the algorithm iterates through the list of template openings for scoring other image combinations in the windows to determine if the baseline is exceeded. If another combination of images in the window openings results in an overall score higher than the baseline score, then that combination becomes our new highest scoring combination and we update our baseline score accordingly. We proceed until another combination again exceeds the current score or until iterations are programmed to end.

The algorithm updates the overall sum total score after each iteration through the list of template openings and images and can run through all possible combinations, until a set time period expires, or until some other programmed stop. The program can iterate through all images, or a subset, comparing a candidate image's attributes with some or all of the template openings' required attributes and computing new candidate image scores. When a candidate image's new fitness score is higher than a currently assigned image's score the algorithm enters into a potential swap condition.

Once the potential swap condition occurs, the image window's existing image can be scored against the candidate image's currently assigned image window and if both images score higher for both image windows then the swap can be selected. Swapping only happens if both images each score higher in the other opening and increase the template's overall score.

The algorithm will, at some point, contain a list of image windows H and a list of images I. A mapping of images to image windows where I₁ maps to H₁, I_(n) maps to H_(n) results in a fitness measurement score. Each image to image window mapping will be scored based on image attributes and required image window's attributes weighting factor. The algorithm can be selected to run for a computed number of iterations (number of images×number of holes or a subset thereof), until a predetermined fitness score is achieved, until the improvement from iteration to iteration is below a predetermined threshold, or until some other programmed cut off.

For each image window opening, the following are programming options:

The algorithm can swap the existing image I_(i) with every image I_(r) in the list of images and perform a weighted attributes fitness measurement score calculation by adding up the attributes weights that the image satisfies and determine if the I_(r) is a better fit with image window H_(i).

If, for example, I_(r) to H_(i) is a better fit then the program can compare both images' (I_(i) and I_(r)) scores with their new possible swapped image windows (H_(i) and H_(r)) to determine if the average weighted attributes fitness measurement score is overall better. If the average fitness measurement score is better the two images' window openings are swapped, if it not, they are not swapped.

After the processing has occurred for each image window opening in a list, a total score for all image to image window mappings will be computed by summing the entire list of image scores and then comparing with the previous total score. If the newer score is better than the previous solution's score, the previous can be replaced with the newer candidate solution.

If we define imageList as the list of input images and imageWindowList as the list of window openings, the following algorithm can be used to iteratively find the optimal image to window opening configuration when the number of images is the same as the number of window openings:

PerformFitting( imageList, imageWindowList) OverallTemplatescore = 0; AssignImagesToImageWindows ( ); FOR each image Window in imageWindowList FOR each image in imageList Calculate newImageWindowScore IF newImageWindowScore > imageWindowScore CheckForSwap(imageWindow, candidateImageWindow) ENDIF END FOR END FOR FOR each image Window in imageWindowList ADD the imageWindow.image.score to OverallTemplatescore END FOR RETURN OverallTemplatescore END PerformFitting CheckForSwap(imageWindow, candidateImageWindow)   currentScore = Calculate2WindowScore(imageWindow, currentimage, candidateWindow, candidateimage)   newScore = Calculate2WindowScore(imageWindow, candidateimage, candidateWindow, currentimage) IF newScore > currentScore THEN SwapImage(imageWindow,candidateImageWindow); ENDIF END CheckForSwap AssignImagesToImageWindows( imageList, imageWindowList )   N = NumberImages; FOR 1=1:N WindowScore[i] = ScoreImage(imageList[i],$$ imageWindow[i]) END FOR End AssigImagesToImageWindows ScoreImage( image,$$ imageWindow) imageScore = 0 FOREACH entry in recipe   imageScore += PerformMeasurement(image, recipeEntry); END FOR RETURN imageScore END ScoreImage

Upon completion of step 940, if automatic mode 944 is enabled, the final user enhanceable product can be assembled, delivered, printed, etc. 946. If automatic option is not turned on, the user has the ability to override 942 the choices made by the image selection process until he or she is satisfied. For example, the user may not like the automatic rearrangement of images done by the automatic algorithm, or it is possible the user may want to select a new image and insert it into the product Once the user is satisfied, the final user enhanceable product can be assembled, delivered, and/or printed 946 as explained above. Referring back to step 905 of FIG. 9, at this point the user has selected their n favorite images. If the number of favorite images n is greater than the number of window openings m in the user enhanceable product the software will select only the top m images. To select the top m images, the metadata and semantic information necessary to fulfill each template opening recipe is automatically extracted from the n images. The individual opening recipes are evaluated for each image at each window opening. As when n=m, such calculations involve a fitness score of each favorite image paired with each window opening, and then the summation of all window opening fitness scores comprises the overall template score.

There are multiple ways to select the optimal image to window opening configuration. The simplest approach is to evaluate the score of each image to each window opening and then assign the highest scoring image to each window opening. If one image has the same score on two window openings, a priority is assigned to each window opening and the image is assigned to the highest priority window opening. If two different images score identically high in one window opening, the image can be assigned based on metadata fields that record the number of times an image was accessed, randomly, or by another programmable procedure.

More sophisticated approaches can be used to maximize the overall template score as a whole. For small m and n, it is reasonable to evaluate all combinations and select the template along with m images arranged having the overall highest fitness score. For large m or n, a linear regression mapping m images to n window openings, where m>n, such as linear least squares or more complex non-linear or iterative approaches can be used, as described below.

Once the top m images are selected, and if automatic mode 912 is enabled, the final user enhanceable product is output 916. If automatic option is not turned on, the user has the ability to override 914 the choices made by the image selection process until he or she is satisfied, at which point the final user enhanceable product 916 is output or assembled, as the case requires.

The third possibility in FIG. 9 is when the number of favorite images n is smaller than the number of window openings m. In this case, the program must search through the user's images and select the top scoring (m−n) images to go along with the n favorites to fill the m window openings. If n and m are small, all possibilities can be tried, and the highest scoring template with the corresponding m favorites and n-m automatically selected images will be used in step 930. Often however, the user image selection can be large, often requiring the analysis of hundreds, and sometimes thousands of images to select the m−n images. In this case, the decision of choosing the highest scoring images to achieve the highest scoring template can be iterative. To speed execution, this process is systematic. If a favorite image is selected it is first evaluated and inserted into the highest scoring window opening. Then other user selected favorite images are inserted into the other window openings such that the highest partial template score is achieved. This leaves (m−n) window openings to fulfill with the user's image collection.

The simplest approach is to evaluate each candidate image to each of the remaining m−n window openings and pick the highest scoring image for each window opening, resolving ties by utilizing a priority with each window opening. When the image selection to pick from is obtrusively large, collecting semantic information for each image can be quite time consuming. A preferred embodiment is to only use recorded metadata to evaluate the fitness of each image as this is fast and can be done on any number of images in a quick fashion. The top x %, or the top p, where x or p is a user defined parameter, images are then selected for further interrogation, by evaluating the semantic information along with the metadata when evaluating the fitness score of each image. Another embodiment of the present invention is to analyze images in a hierarchical fashion. In the first layer, all images are evaluated by metadata alone. The top x % or p images are passed to the second round. In the second round, simpler, or fast semantic algorithms, such as color or histogram semantics are evaluated in the second round, where the top y % or q images are passed to the third round. In the third round, slightly more complex semantic algorithms such as face detection are evaluated and the top z % or r images are passed to the fourth round. In the fourth, final round, the most complex semantic algorithms such as facial recognition, custom object detection are performed. This can be extended to any number of rounds. As we go from the first to last round, the number of candidate images shrinks, but the computational complexity of each analysis increases.

Additional programming features can be optionally implemented as follows:

In step 770, all template selection items were completed by default. In step 780, some of those default selection items were overridden by the consumer. For example, for step 780, all template options may be the same as in step 770 except that the user may override the number of window openings by reducing the total to two. Thus, in FIG. 10, at step 1010, the program begins to determine which template will be selected, given the selection of user imagery. For example, if all user images are identified as fall scenes, then a fall oriented template would score the highest. If no source of input images can be automatically determined by the computer system, the user is prompted for such images 1020. If manual mode is enabled, the user may decide to manually select one or more favorite images 1005. If manual mode is disabled, the users images are automatically selected 1040. The selection of favorite images 1030 can involve the user previewing thumbnail size images on a display screen and marking favorite images. The user can select as many images as desired, however, selection can be limited by program to a number z, where z is equal to the number of window openings in the product with the most window openings, in this example z=2. Therefore, creating and storing a number of templates having the same theme but each with a different number of windows can better accommodate user preferences. Once again, we will assume there is no image splitting. In addition to selecting favorite images, the user is given the option of selecting their overall favorite, primary, or “hero” image.

The highest scoring template is chosen 1040 by pairing the image set with the available templates in the system. If a user has picked favorite images, these images, or a subset of these images can be required by programming to be included in the final user enhanceable product. If a “hero” image is marked, the template selected must have a “hero” window opening that is highly compatible with the “hero” image selected by the user. When scoring each template, each template is initially set to zero. It is possible for a manufacturer or retailer, to bias the creation of some templates over others by purposely initializing such templates at a higher score. For example, templates that generate more royalties, or that are faster to process, or that yield higher quality products may be preset at higher levels to encourage their usage over less desirable templates. Similarly, templates that are not desired may be given negative scores. If a single template is always to be used, it is given a score of positive 1000. Of course, if two or more templates are prescored at 1000, the one with the highest score after image evaluation is chosen. In the case of a tie, all templates can be assigned a numeric priority, and the template with the highest priority is chosen.

The decision of choosing the highest scoring template can be iterative. Each template in the system is evaluated one at a time across all images. To speed execution, this process is hierarchical. If a hero image is selected it is first evaluated across all templates. The top x %, where x is an adjustable/selectable parameter, templates are evaluated further, and the bottom (100−x) % templates are discarded. After the hero selection, the favorite images are scored in each template in each window opening. The highest scoring configuration for each template is stored. If n>m (if user favorite image is greater than window openings), then the selection is complete. If not, the program picks the top y %, where y is an adjustable parameter, and templates are evaluated further, and the bottom (100−y) % templates are discarded. Once again, for the remaining window openings in each remaining template, each image is evaluated and the top scoring templates are recorded. This hierarchical approach greatly speeds up program execution, especially when there are many templates, and many images to evaluate.

After the top scoring template is chosen, in automatic mode 1060, this template is selected by the algorithm 1070 and it along with its chosen images are passed to step 1125 in FIG. 11. If automatic mode is disabled, the user is prompted for acceptance 1015 of the template. If the user rejects this template, the rest of the templates are offered to the user in order of decreasing score. Eventually, the user will select one of the templates 1070 and it passes to step 1125 in FIG. 11.

Referring now to FIG. 13, a sample list of recorded metadata tags obtained from image acquisition and utilization systems including digital stand-alone cameras, cell phone cameras, personal computers, digital picture frames, camera docking systems, imaging appliances, networked displays, and printers. Recorded metadata is synonymous with input metadata and includes information recorded by an imaging device automatically and from user interactions with the device. Standard forms of recorded metadata include; time/date stamps, location information provided by global positioning systems (GPS), nearest cell tower, or cell tower triangulation, camera settings, image and audio histograms, file format information, and any automatic images corrections such as tone scale adjustments and red eye removal. In addition to this automatic device centric information recording, user interactions can also be recorded as metadata and include; “Share”, “Favorite”, or “No-Erase” designation, “Digital print order format (DPOF), user selected “Wallpaper Designation” or “Picture Messaging” for cell phone cameras, user selected “Picture Messaging” recipients via cell phone number or e-mail address, and user selected capture modes such as “Sports”, “Macro/Close-up”, “Fireworks”, and “Portrait”. Image utilizations devices such as personal computers running Kodak Easy Share™ software or other image management systems and stand alone or connected image printers also provide sources of recorded metadata. This type of information includes print history indicating how many times an image has been printed, storage history indicating when and where an image has been stored or backed-up, and editing history indicating the types and amounts of digital manipulations that have occurred.

FIG. 14 contains a sample list of extracted metadata tags obtained from analysis of image content and existing recorded metadata tags. Extracted metadata tags can be created by image acquisition and utilization systems including standalone digital cameras, cell phone cameras, personal computers, digital picture frames, camera docking systems, imaging appliances, networked displays, and printers. Extracted metadata tags can be created automatically when certain predetermined criteria are met or from direct user interactions. An example of the interaction between extracted metadata and recorded metadata is using a camera generated image capture time/date stamp in conjunction with a user's digital calendar. Both systems can be co-located on the same device as with a cell phone camera or can be dispersed between imaging devices such as a camera and personal computer camera docking system. A digital calendar can include significant dates of general interest such as: Cinco de Mayo, Independence Day, Halloween, Christmas, and the like and significant dates of personal interest such as; “Mom & Dad's Anniversary”, “Aunt Betty's Birthday”, and “Tommy's Little League Banquet”. Camera generated time/date stamps can be used as queries to check against the digital calendar to determine if any images were captured on a date of general or personal interest. If matches are made the metadata can be updated to include this new extracted information. Further context setting can be established by including other extracted and recorded metadata such as location information and location recognition. If, for example, after several weeks of inactivity a series of images and videos are recorded on September 5^(th) at a location that was recognized as “Mom & Dad's House”. In addition the user's digital calendar indicated that September 5^(th) is “Mom & Dad's Anniversary” and several of the images include a picture of a cake with text that reads, “Happy Anniversary Mom & Dad”. Now the combined extracted and derived metadata can automatically provide a very accurate context for the event, “Mom & Dad's Anniversary”. With this context established only relevant theme choices would be made available to the user significantly reducing the workload required to find an appropriate theme. Also labeling, captioning, tagging, or blogging, can be assisted or automated since the event type and principle participants are now known to the system.

The content of image, video, and audio assets can be analyzed using face, object, speech, and text identification and algorithms. The number of faces and relative positions in a scene or sequence of scenes can reveal important details to provide a context for the images. For example a large number of faces aligned in rows and columns indicates a formal posed context applicable to family reunions, team sports, graduations, and the like. Additional information such as team uniforms with identified logos and text would indicate a “sporting event”, matching caps and gowns would indicate a “graduation”, and assorted clothing may indicate a “family reunion”, and a white gown, matching colored gowns, and men in formal attire would indicate a “Wedding Party”. These indications combined with additional extracted and derived metadata provide an accurate context that enables the system to select appropriate images, provide relevant themes for the selected images, and to provide relevant additional images to the original image collection.

In another preferred embodiment of the present invention, a unique template recipe is used for large venue displays, such as stadium scoreboards, for informational or entertainment purposes. For example, the template illustrated herein in FIG. 3 represents in most respects a generic electronic scoreboard used for sporting events or a large electronic display at concerts, plays, entertainment shows, trade shows, conferences, political conventions, rallies, etc. Also, the display 66, such as in FIG. 2, illustrates the coupling of a large scoreboard to a computer system 34. FIG. 15 illustrates an example installation of these systems as described herein at a sports or entertainment event at an arena. A scoreboard embodiment 190 of display 66 is shown within a sports arena for display to the crowd 151. Cameras 76 are mounted in stationary positions within the arena and are coupled to computer system or sever 26 which controls scoreboard display 190. As described previously, the cameras can alternatively be hand carried and wirelessly coupled to system 26.

Templates are created in advance by artistic teams based upon feedback from event specialists. For example, we may have a digital scoreboard at a baseball game. During innings of play, the template can have three windows, one with a live close-up of the pitcher, one of a live close-up of the batter, and a third window showing an animation of the last pitch showing where it landed in the strike zone. In-between innings, the template can switch to highlights of the previous inning, interesting videos of the sport, or funny-entertaining events in the stadium. For example, during the typical seventh inning stretch, the template can have one large background window opening of a narrated video of “Take me out to the ballgame”. Other windows, with transparency going back and forth between 100% translucent (appear) and 100% transparent (disappear) can show live or recorded video or still shots of the crowd. Window opening 2 can be choreographed such that when the song gets to the phrase “buy me some peanuts and cracker jacks”, a live video of a walking vendor at the very same game is shown; or when the song arrives at the phrase “for it's one, two, three strikes your out”, a live shot of a singing youngster at the game is shown. While human or automatically operated cameras at the game are directed toward various sections of the stadium, an embodiment of the present invention can be employed at a central server to receive inputs from cameras at the stadium, to store assorted templates with associated recipes, and to selectively control an output feed to the stadium scoreboard to automatically display programmably selected templates with programmably selected images fed from the various stadium cameras disposed in openings therein. The implementation includes content of these templates that is partly done in advance, while the rest of the content is temporal, i.e. live, and is unknown at the time the template is written. The creative freedom for the template theme and overall design still remains with the designer. For example, in the previous example, the template designer can specify that the singing youngster be a boy approximately 7 years old wearing a baseball cap and raising an arm in the air. Multiple video cameras, mounted and remotely controlled, or hand held, are constantly collecting and storing still images or video snippets of the crowd or simply feeding live video in order to provide the next recipe item, and the video shot that matches the recipe specification the closest is selected by program control for selection in the live video scoreboard window, or still image window, or recorded video window. The central server then uses inputs from the rest of the cameras to identify images for the next recipe specification. At sporting events this can be couples kissing, a group of fans screaming, a baby sleeping, or a person eating a hot dog.

Live video and choreographed windows, are implemented through new recipe key value pairs. The switching from one recipe to the next, for example, based upon inning of the ballgame, or when a home run is scored is performed via wrapper scripts, triggered electronically or manually. For an example of a trigger, anytime the main scoreboard records a third out, we know it is the end of an inning; or, anytime the pitch speed pops up on radar, we know a new pitch has been thrown. Alternatively, a master operator manually switches from one recipe to the next. The application displays a still image when it recognizes still formats with extensions such as JPG, BMP, PNG, etc; and displays video when it recognizes video format extensions such as MOV, WMV, etc. The following two recipe lines enforce that a defined window must contain a video sequence.

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“Video” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“VideoWeight” Datum=“100” />

Just as still images are scored and the image with the highest fitness score is selected for inclusion in the window opening, all videos are also scored and the highest scoring video is used in the window opening. To make this process faster, the usage of metadata in video feeds is often used to prevent the fitness score calculation of all frames in a video sequence. Alternatively, the system can be setup to analyze n frames from each video sequence. If n=10, and we have a 2 minute video sequence at 30 frames/second, we analyze every 2*30*60/10=360^(th) frame. Alternatively, we can use key frame extraction algorithms and analyze the top n key frames. To avoid rogue frames from skewing the overall fitness score, we take the median score of each candidate frame and report that as the video fitness score.

When searching for images and videos, the system needs to know where to look. Generally this is done via default search paths. Live still frame or video feed might require a separate port for each feed. In such a case, the InputLive key value pair, shown below, tells the recipe to not search the default search paths, but instead search the available input ports.

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“InputLive” Datum=“1” />

The signal over these ports can transmit still frames or video sequences. These input ports are configured during setup. In the base case, built-in firewire and USB ports are searched. In more advanced applications we can have dozens, if not hundreds, of cameras being fed into the system simultaneously. This is similar to the multitude of video inputs to a producers switchboard for a sporting broadcast. Each input video stream is analyzed and its fitness is calculated. The highest scoring video feed is then fed to the window opening. As indicated above, a recorded and stored video can be preliminarily scored and saved for playback a short time later during the game. For example, a video recorded during the third inning might be preferred for playback in a template window on the scoreboard during the seventh inning stretch program.

One key difference between live video and stored video files on disk is that on stored files, fitness scores can be calculated and stored to indicate what is in the stored video sequence. In live sequences we could calculate the fitness of the previous m frames, optionally skipping every nth frame, then take the median fitness score. All live video feeds are analyzed in parallel, and the one with the highest score at the time requested gets redirected to the live video feed window opening in the template.

As a practical implementation strategy a preselected amount of video can be buffered. This buffered data is analyzed, and the buffered sequence is ultimately displayed in the template opening. To speed execution, each buffer is treated in a FIFO manner and only newly arriving frames need to have their fitness evaluated. Using this embodiment, the buffer can be several minutes long, and median fitness execution speed will not suffer.

Some templates might require long video sequences, others short. It would be preferable, especially in the buffered setup previously described, to specify the exact length of the sequence such that the fitness is scored over the proper temporal period. This can be accomplished with the VideoLength key value pair as shown below:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“VideoLength” Datum=“45.2” />

Where the 45.2 is the length in seconds of the video sequence. Recipe scripts will allow a designer to further choreograph the display such that windows appear and disappear and content changes on the fly. The template and each window opening can have its own script. The script controls the template in a temporal fashion. Each time a template is started, it is by default started at t=0 seconds offset, but any time offset is possible. A long template can be temporarily interrupted, then returned where it left off. Time based recipe scripts (for each template and window opening) may look like the following:

< MetaDatum Label=“ EastmanKodakCompany ” Tag=“RecipeDurationMin” Datum=“2.1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Video” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“InputLive” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Title” Datum=“Crowd” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Title” Datum=“Mezzanine” /> < MetaDatum Label=“ EastmanKodakCompany ” Tag=“Label” Datum=“SecondRecipe” /> < MetaDatum Label=“ EastmanKodakCompany ” Tag=“RecipeDurationSec” Datum=“7.3” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Video” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“InputLive” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“VideoLength” Datum=“7.3” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Title” Datum=“Crowd” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Title” Datum=“3rdBaseBox” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FacialCloseToNum” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“AgeClosetoNum” Datum=“7” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“FacialEpression” Datum=“Happy” /> < MetaDatum Label=“ EastmanKodakCompany ” Tag=“Label” Datum=“ThirdRecipe” /> < MetaDatum Label=“ EastmanKodakCompany ” Tag=“RecipeDurationHour” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Video” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“InputLive” Datum=“1” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Title” Datum=“Crowd” /> <MetaDatum Label=“ EastmanKodakCompany ” Tag=“Title” Datum=“Mezzanine” />

For ease of reading, the above recipe has been broken up into three segments separated by a blank line. The first line of the first segment says the first recipe will apply to the current window opening for the next 5.6 minutes. The specifications are for a live video, and the scoring of live video is done only based upon metadata tags. In this case any camera that is focused on the crowd in the mezzanine will score equally high. When more than one feed scores equally, one is chosen at random.

After 5.6 minutes, the recipe script goes to the next segmented recipe. If the next line is a new recipe, the new recipe will be fulfilled. If this is the last recipe in the script, the current recipe will stay in effect until the system is reset. With respect to the second segment above, the first line is a label. Labels can be used as a form of GOTO's when a template is started. Upon startup, a template can jump to a specified time=t seconds, or to a particular label. If the label does not exist, or the recipe is not defined for t seconds, the last segment recipe is used for fulfillment.

The second segment will apply to the current window for 7.3 seconds. It is a live video feed. To score high, the video feed should: be of the crowd; someone in the third base line side box seats; contain one person; that person's age should be close to seven years old; and that person should be smiling. Note also that the VideoLength tag was used, so that when used in conjunction with buffered cameras, the last 7.3 seconds are used in the fitness score.

The third segment is of length 1 hour or, since it is the last segment in this example, it will run continuously until the template is reset. This third segment, like the first, looks for a live video feed of the crowd in the mezzanine level.

Using time durations, complex templates can be created that appear to be ever changing. To allow for complex looping, a GOTO command is added to jump to any Label as follows:

<MetaDatum Label=“ EastmanKodakCompany ” Tag=“GOTO” Datum=“SecondRecipe” />

Furthermore, routines that startup recipe scripts at some labeled offset, where the startup of such a recipe script is based upon some external event, can make the display appear to be quite intelligent. For example, at the ballpark, anytime the scoreboard records “out=3”, we restart the template with offset=“InningBreak”. Or, anytime the radar gun posts a new pitch speed, we display the animation showing where the pitch landed with respect to the strike zone. These triggering events can be implemented electronically, mechanically, or by manual intervention. For example, an operator at a console can jump to various portions of a temporal recipe according to its label. Using similar concepts, temporal recipes can be implemented on an electronically controlled display at any event. There is an initial time investment of writing the recipes, so for practical purposes this limits applications to those in which there is a financially accountable return on investment. In the baseball example, a cleverly templated scoreboard may entertain and entice spectators to return more often to the ballpark. In other events, say at a Presidential Ball, there is no financial return, but rather the ability to impress the attendees with technology of high stature.

PARTS LIST

-   22 housing -   24 system -   26 system -   28 system -   29 printer -   30 printer -   32 I/O -   34 processor -   35 I/O -   38 sensor -   39 memory -   40 storage -   42 storage -   44 storage -   46 comm -   48 memory -   50 interface -   52 memory -   54 system -   56 I/O -   58 I/O -   58 a I/O -   58 b I/O -   58 c I/O -   66 I/O -   68 I/O -   68 a I/O -   68 b I/O -   70 system -   72 user -   201 sensor -   300 image enhanceable item -   302 image receiving area -   306 window area -   308 window area -   310 window area -   312 inter-window area -   320 decorative background image -   330 decorative background image -   610 image -   620 image -   630 image -   640 image -   615 label -   625 label -   635 label -   645 label -   640 image -   660 image -   670 image -   705 step -   710 step -   715 step -   720 step -   725 step -   730 step -   740 step -   750 step -   760 step -   770 step -   780 step -   805 step -   810 step -   815 step -   820 step -   830 step -   840 step -   850 step -   860 step -   870 step -   905 step -   910 step -   912 step -   914 step -   915 step -   916 step -   925 step -   930 step -   932 step -   934 step -   935 step -   936 step -   940 step -   942 step -   944 step -   945 step -   946 step -   1005 step -   1010 step -   1015 step -   1020 step -   1030 step -   1040 step -   1050 step -   1060 step -   1070 step -   1105 step -   1125 step -   1130 step -   1140 step -   1150 step -   1160 step -   1210 step -   1220 step -   1230 step -   1240 step 

1. A computer implemented method of generating an image display, comprising the steps of: automatically selecting a digital image template having template attributes and having at least one designated location for disposing a digital image; capturing digital images in an electronic camera including transmitting the captured images, each of the captured digital images comprising a plurality of image elements; receiving the captured digital images; automatically selecting at least one of the received digital images whose image elements correspond to the template attributes and disposing the at least one selected image in the at least one designated location; and displaying on an electronic display the digital template with the at least one selected image disposed in the at least one designated location.
 2. The method of claim 1 wherein the at least one digital image is a motion digital image and wherein the displaying step includes displaying the motion digital image in the at least one designated location.
 3. The method of claim 2 wherein the motion digital image is a live motion digital image.
 4. The method of claim 1 wherein the step of receiving includes the step of receiving the digital images over a wireless network.
 5. The method of claim 1 wherein the step of receiving includes the step of receiving the digital images over a LAN.
 6. The method of claim 1 wherein the digital images are selected from the group consisting of motion video images, digital still images, and prestored graphics images.
 7. The method of claim 1 wherein the at least one selected image is an animated version of one of the captured images.
 8. The method of claim 1 further comprising displaying the electronic display to a plurality of people and said at least one selected image includes one of the plurality of people.
 9. The method of claim 8 wherein said plurality of people are all located in an arena or a stadium, and the electronic display includes an arena display or stadium display.
 10. The method of claim 9 wherein the step of capturing digital images is performed by a roving camera at the arena or stadium.
 11. The method of claim 9 wherein the step of capturing digital images is performed by a stationary camera at the arena or stadium.
 12. A computer implemented method of generating a scoreboard display, comprising: capturing and storing digital images at an entertainment venue during an entertainment event; selecting at least one of the captured images including selecting at least one template within which to dispose the at least one selected image; and displaying on the scoreboard the template and the at least one selected digital image disposed therein.
 13. The method according to claim 12 wherein the step of capturing includes the step of capturing at least one digital image of a person attending the entertainment event
 14. The method according to claim 12 wherein said at least one of the captured images is a motion image.
 15. The method according to claim 14 wherein said at least one of the captured images is a live motion image. 